Logica fuzzy

Da WikiDsy.
Versione del 11 nov 2012 alle 11:55 di Mattiie (discussione | contributi) (Aggiunta la mia dimostrazione di TAUT_g subset TAUT)
Disambigua compass.PNG
Questa è una pagina di introduzione al corso: contiene i turni, le modalità d'insegnamento, alcune informazioni generali ed eventuali giudizi sul corso in questione. Se sei giunto qui passando da un link, puoi tornare indietro e correggerlo in modo che punti direttamente alla voce appropriata.

A.A. passati

Information

Course's website
Times and classrooms:
Monday 15:30 - 17:30 - Room 5 (Ground floor - via comelico 39)
Friday 10:30 - 12:30 - Room 5

Lessons' notes

This notes are written in english to help foreign students to follow this course.

Classical Propositional Logic

We are going to describe the classical propositional logic (L.P.C) language.

Syntax

The syntax of a language is the set of rules that specify how the elements of the language are formed regardless their meaning.

Let {\mathbb  {N}}=\{1,2,...\} be the set of the natural numbers and {\mathbb  {A}}=\{(,),X,|,\$,\rightarrow ,\land ,\lor ,\neg ,\top ,\bot \} an alphabet of symbols.
The symbols \bot ,\top are called respectively "falsum", "verum".
{\mathbb  {A}}^{\star } is the set of strings on this alphabet. For example ''(\top \land \bot )'',''(\neg \land '',''X((''\in {\mathbb  {A}}^{\star }.
We have now to define the set of the "well formed formula" FORM, that is the set of the elements of the L.P.C.
Definition (well formed formulas). FORM\subset {\mathbb  {A}}^{\star } is defined with some conditions:

  1. \top ,\bot \in FORM
  2. \forall n\in {\mathbb  {N}}
    \qquad X||...|\$\in FORM, where | is taken n times. For example: X|\$,X||\$,X|||\$,....\in FORM
  3. if \alpha ,\beta \in FORM, then (\neg \alpha )\in FORM.
  4. if \alpha ,\beta \in FORM, then (\alpha \land \beta )\in FORM.
  5. if \alpha ,\beta \in FORM, then (\alpha \lor \beta )\in FORM.
  6. if \alpha ,\beta \in FORM, then (\alpha \rightarrow \beta )\in FORM.

Well formed formulas is often abbreviated with f.b.f. The strings in condition (2) are called "propositional variables" or "atomic formulas" or "propositional letters" or simply "variables". They are abbreviated with this notation: X_{1},X_{2},X_{3},...,X_{n}(In other books p, q, r, .., are used to refer to variables).
The set of variables is VAR.
VAR\subset FORM
Example of well formed formulas:
(((X_{1}\land X_{2})\lor \top )\rightarrow (X_{1}\lor \bot ))\in FORM
Instead
(X_{1}\land \land )\notin FORM
In this notes we omit (, ) where it is clear the precedence of the connectives. (Connectives are \neg ,\land ,\lor ,\rightarrow ,\bot ,\top )
Why don't we use directly X_{1},X_{2},... or p,q,r,s,...?
Because it is important that the alphabet is a finited set. Although, in this notes, we use X_{1},X_{2},...,notation. It is essential, even, that the L.P.C. language is decidable, that is it must exist an algorithm that tell us if a string is \in FORM or not. For this reason it is crucial the
Unique readability of well formed formulas. For all \alpha \in FORMone (and only one) of the following sentences must be true:

  1. \alpha =\bot or \alpha =\top but not both.
  2. Exists an unique n\in {\mathbb  {N}} such that \alpha =X_{n}.
  3. Exists an unique \beta \in FORM such that \alpha =(\neg \beta ).
  4. Exist unique \beta ,\gamma \in FORM such that \alpha =(\beta \land \gamma ).
  5. Exist unique \beta ,\gamma \in FORM such that \alpha =(\beta \lor \gamma ).
  6. Exist unique \beta ,\gamma \in FORM such that \alpha =(\beta \rightarrow \gamma ).

Let's, infact, consider the parser of the algorithm we talked above: When it find, for example, \neg (\alpha \land \beta ), to decide if the string belongs to FORM, it have to decide (for the unique readability of well formed formulas) if \alpha \land \beta \in FORM. But how can it do this? Deciding if \alpha \in FORM and \beta \in FORM. This is what the above theorem tell us. Try to draw the parser tree. It is unique thanks to, again, that theorem.

Formally, a string \alpha is a finite sequence of elements: \alpha =s_{1}s_{2}...s_{n},s_{i}\in {\mathbb  {A}},i\in \{1,..,n\}
A substring of \alpha is a string in the form s_{i}s_{{i+1}}...s_{{i+j}}, where j\in \{0,1,..,n\} and i+j\leq n.
A subformula is a substring \in FORM.
For example: \alpha =(X_{1}\land X_{2})\rightarrow \top
\beta =(X_{1}\land \qquad \gamma =(X_{1}\land X_{2})
\beta ,\gamma are both substring of \alpha but only \gamma is a subformula. With Var(\alpha ) we indicate the set of variables that are subformulas of \alpha . With \alpha (X_{1},X_{2},..,X_{n}) we denote a formula whose variables are a subset of \{X_{1},X_{2},..,X_{n}\}.

Semantic

The semantic of a language is the relation between the elements of that language and their meaning.
The set {0,1} is called truth values set. 0 means false and 1 means true. Definition(Assignment). An atomic assignment is any function
\mu _{0}:Var\rightarrow \{0,1\}.
An assignment (or interpretation) is a function
\mu :FORM\rightarrow \{0,1\}
that extends \mu _{0} and respects the following rules for every \alpha ,\beta \in FORM.

  1. \mu (\bot )=0 and \mu (\top )=1
  2. \mu ((\neg \alpha ))={\begin{cases}1&if\quad \mu (\alpha )=0\\0&if\quad \mu (\alpha )=1\end{cases}}
  3. \mu ((\alpha \land \beta ))={\begin{cases}1&if\quad \mu (\alpha )=1\quad and\quad \mu (\beta )=1\\0&else\end{cases}}
  4. \mu ((\alpha \lor \beta ))={\begin{cases}1&if\quad \mu (\alpha )=1\quad or\quad \mu (\beta )=1\quad or\quad both\\0&else\end{cases}}
  5. \mu ((\alpha \rightarrow \beta ))={\begin{cases}0&if\quad \mu (\alpha )=0\quad and\quad \mu (\beta )=1\\1&else\end{cases}}

Informally we can say that the variables represent propositions with one verb and one or more complement. For example:
X_{1}= "It rains";
X_{2}= "I go to school".
\neg X_{2}= "I don't go to school"
X_{1}\land X_{2}= "It rains and I go to school"
X_{1}\lor X_{2}= "it rains or I go to school"
X_{1}\rightarrow X_{2}= "If it rains then I will go to school"
I can choose \mu _{0} such as \mu _{0}(X_{1})=1 and \mu _{0}(X_{2})=0
Consequently we have
\mu (\neg X_{2})=1\quad \mu (X_{1}\land X_{2})=0\quad \mu (X_{1}\lor X_{2})=1\quad \mu (X_{1}\rightarrow X_{2})=0

Proposition (Unique extendibility of atomic assignment): Every atomic assignment \mu _{0}:Var\rightarrow \{0,1\} admits exactly one extension to an assignment \mu :FORM\rightarrow \{0,1\}

More informally, as you can see in the example above, when we choose the values of the variables we determinate the values of the formulas within those variables.

Definition (truth and falsehood). Let \alpha \in FORM. When we have \mu (\alpha )=1 we say that \alpha is true in the interpretation of \mu , or \mu is a model of \alpha . Instead, when we have \mu (\alpha )=0 we say that \alpha is false in the interpretation of \mu , or \mu is an anti-model of \alpha .
In symbols:
\mu \models \alpha when \mu (\alpha )=1
\mu \not \models \alpha when \mu (\alpha )=0.
When \alpha is true for every \mu we say that \alpha is a tautology. Instead when we have \alpha false for every assignment \mu we say that \alpha is a contradiction. When exists a \mu such as \mu (\alpha )=1 we say that \alpha is satisfiable; instead when exists a \mu such as \mu (\alpha )=0 we say that \alpha is refutable.
In symbols:
\models \alpha tautology
\not \models \alpha refutable

In these notes we abbreviate
((\alpha \to \beta )\land (\beta \to \alpha ))
with
(\alpha \leftrightarrow \beta )
and it can be read as "if and only if".

Exercise. Prove that the following formulas are tautologies for all \alpha ,\beta \in FORM
Hint: use the truth table

  1. \alpha \lor \neg \alpha (Excluded middle)
  2. \neg (\alpha \land \neg \alpha ) (Not contradiction)
  3. \neg \neg \alpha \leftrightarrow \alpha (Law of double negation)
  4. \neg (\alpha \land \beta )\leftrightarrow \neg \alpha \lor \neg \beta (De Morgan rule I)
  5. \neg (\alpha \lor \beta )\leftrightarrow \neg \alpha \land \neg \beta (De Morgan rule II)
  6. \alpha \land \neg \alpha \to \beta (Ex falso quodlibet)
  7. (\alpha \to \beta )\lor (\beta \to \alpha ) (Prelinearity)

Exercise. Prove that exist \alpha ,\beta \in FORM for those the following formulas aren't tautologies. Which of these are contradiction?
Hint: to prove that a formula isn't a tautology is sufficient an counter-example but to prove that it is a contradiction it isn't sufficient. You can use the truth table again.

  1. X_{1}
  2. \alpha \to \neg \alpha
  3. (\alpha \to \beta )\to (\neg \alpha \to \beta )
  4. \neg ((\alpha \to \beta )\to (\neg \beta \to \neg \alpha ))

Relationship between syntax and semantic

Definition (Axioms of LPC (Classical propositional logic)). For all \alpha ,\beta ,\gamma \in FORM, let's consider the following formulas.

  1. \alpha \to (\beta \to \alpha )
  2. (\alpha \to \beta )\to ((\alpha \to (\beta \to \gamma ))\to (\alpha \to \gamma ))
  3. \alpha \to (\beta \to (\alpha \land \beta ))
  4. (\alpha \land \beta )\to \alpha
  5. (\alpha \land \beta )\to \beta
  6. (\alpha \to (\alpha \land \beta ))
  7. (\alpha \to (\alpha \land \beta ))
  8. (\alpha \to \gamma )\to ((\beta \to \gamma )\to ((\alpha \lor \beta )\to \gamma ))
  9. (\alpha \to \beta )\to ((\alpha \to \neg \beta )\to \neg \alpha )
  10. \alpha \to (\neg \alpha \to \beta )
  11. \neg \neg \alpha \to \alpha

The formulas between 1 and 11 \in AXIOM\subset FORM.
AXIOM is called set of the axioms of the classical propositional logic.
Why these formulas are axioms and not others? Because they are needed to prove the theorem of completeness that is very important for logic. We will talk about this theorem later.. The cardinality of AXIOM is \infty because \alpha ,\beta ,\gamma can be other formulas. For example:
Let \alpha :=\beta \land \gamma and substitute in the first axiom; it becomes
(\beta \land \gamma )\to (\beta \to (\beta \land \gamma ))\in AXIOM
It is important to understand that the axioms are defined only through syntax, because we don't speak about values of formulas. Axioms, for definition, are demostrable without demonstration. Think about syntax and semantic as two different worlds. In "syntax world" there are AXIOM\subset FORM but even THM, the set of theorems. So we have
AXIOM\subset THM\subset FORM
The elements of THM are the demonstrable formulas.
Definition. We say that a formula \alpha is demonstrable (or syntactic consequence), \vdash \alpha if exist a finite sequence of formulas \alpha _{1},\alpha _{2},...,\alpha _{n}\quad n\in {\mathbb  {N}} such that \alpha _{n}=\alpha ,\forall i\in \{1,..,n\}one of the following conditions is true.

  • \alpha _{i}\in AXIOM
  • Exist indexes j,k\in {1,..,n}\quad j,k\leq i such that \alpha _{i} is deducible from \alpha _{j} and \alpha _{k} through modus ponens.

A sequence of formulas like that is a formal demonstration of \alpha .
Definition (modus ponens). Let \alpha ,\beta \in FORM. We say that \gamma \in FORM is deducible, through modus ponens, if \alpha =(\beta \to \gamma ). For example:
\alpha :="If it rains then I will stay home" \beta :="It rains" \gamma :="I go to school". We know that \alpha ,\beta are true, hence we can say that \gamma is true.

The elements of THM are found in this way through modus ponens starting from elements of AXIOM. Modus ponens is one of the inference rules. Example of demonstration: We want to prove that \gamma \to ((\gamma \land \delta )\to \gamma )\in THM. We start from axioms 1, 4.

1A \alpha \to (\beta \to \alpha )

4A (\alpha \land \beta )\to \alpha

\alpha \longmapsto (\gamma \land \delta )\to \gamma \qquad \beta \longmapsto \gamma (substitution of \alpha ,\beta in A1 (first axiom)
\alpha _{1}:=((\gamma \land \delta )\to \gamma )\to (\gamma \to (\gamma \land \delta )\to \gamma ))\in AXIOM \alpha \longmapsto \gamma \qquad \beta \longmapsto \delta (substitution in A4)
\alpha _{2}:=(\gamma \land \delta )\to \gamma \in AXIOM
Now we have \alpha _{1}=(\alpha _{2}\to \alpha _{3}) hence we can conclude that
\alpha _{3}=\gamma \to ((\gamma \land \delta )\to \gamma )\in THM

It is really hard to find theorems in this way: in this course we don't have to learn this, just have to know how a formal syntactic demonstration are made. Thanks to completeness and validity theorem we can prove theorem through an easier way; infact it says that THM\equiv TAUT the set of theorems and the set of tautologies coincide. Hence, proving that a formula is a tautology is equals to prove that a formula is a theorem. This is the bridge between Syntax and Semantic.

Theorem of validity and completeness. For all \alpha \in FORM we have
\vdash \alpha \leftrightarrow \models \alpha

The demonstrable formulas coincide with tautologies.

Example: If I prove that \neg (\alpha \land \neg \alpha )\in TAUT (using truth table or by reduction to absurd or any other way that use the values of the formulas (semantic)) then, it must exist a syntactical demonstration (starting from axioms and going on through modus ponens) to prove that formula.

We can divide the theorem in two part:

  1. Theorem of validity:
    \vdash \alpha \to \models \alpha
  2. Theorem of completeness:
    \vdash \alpha \leftarrow \models \alpha

It is very difficult to prove the theorem of completeness (in this course it isn't requested), but it is simple to prove the theorem of validity.

Theorem of validity proof: Before prove this theorem we have to prove that modus ponens (MP) preserves tautology:

\forall \alpha ,\beta \in FORM if \alpha ,(\alpha \to \beta ) are tautologies then \beta is a tautology.
Proof by absurdity: Let's suppose \mu (\alpha )=1,\mu (\alpha \to \beta )=1,\mu (\beta )=0
We have a contraddiction because \mu (\alpha \to \beta )=0
So MP preserves tautologicity.
Now we can face theorem of validity proof: \forall \alpha \in FORM\vdash \alpha \to \models \alpha infact the hypothesis \vdash \alpha means:

  1. \exists \alpha _{1},\alpha _{2},..,\alpha _{n}\in FORM such that\alpha _{n}=\alpha
  2. \forall i=1,..,n
    1. or \alpha _{i}\in AXIOM (then is a tautology for definition)
    2. or \alpha _{i} is proved by modus ponens.

So, thanks to preservation of tautologicy of MP, we have that \alpha \in TAUT

When a logic is decidable? When exists a program that:
Input: \alpha \in FORM
Output: YES, if\alpha \in THM, else NO.
The classical propositional logic is decidable because, for the theorem of completeness (and validity), we have THM=TAUT, so the program can make the truth table of the formula and then check if all the evaluation are 1. Infact, if a formula's truth table have all the entry 1, we can say that \alpha \in TAUT and so \alpha \in THM.

Godel logic

Syntax

The syntax of Godel logic is the same of the syntax of the classical propositional logic, so we have that FORM_{G}=FORM_{{LC}}.
So we can write FORM.

Semantic

The semantic in the Godel logic is polyvalent infact \alpha \in FORM assumes values in [0,1].
When:

  1. \mu (\alpha )=0 we say that \alpha is false, or absolutely false;
  2. \mu (\alpha )=1 we say that \alpha is true, or absolutely true;
  3. \mu (\alpha )\in (0,1) we cannot say that \alpha is true neither false. Although these values represent difference degrees of truth.

For example:
\mu (\alpha )=0.7\qquad \mu (\beta )=0.3 we can say that \alpha is truer then \beta .
Infact let \alpha ="Matteo is young" and \beta ="Matteo is old".
I'm 23 so I can say that I'm not absolutely young and not absolutely old so we can assign a value 0.7 to \alpha and 0.3 \beta because I'm more young than old.

Definition(Assignment). An atomic assignment is any function
\mu _{0}:Var\rightarrow [0,1].
An assignment (or interpretation) is a function
\mu :FORM\rightarrow [0,1]
that extends \mu _{0} and respects the following rules for every \alpha ,\beta \in FORM.

  1. \mu (\bot )=0 and \mu (\top )=1
  2. \mu ((\neg \alpha ))={\begin{cases}1&if\quad \mu (\alpha )=0\\0&if\quad \mu (\alpha )>0\end{cases}}
  3. \mu ((\alpha \land \beta ))=min(\mu (\alpha ),\mu (\beta ))
  4. \mu ((\alpha \lor \beta ))=max(\mu (\alpha ),\mu (\beta ))
  5. \mu ((\alpha \rightarrow \beta ))={\begin{cases}1&if\quad \mu (\alpha )\leq \mu (\beta )\\\mu (\beta )&else\end{cases}}

This is the sematic of Goedel logic but it is not the only fuzzy logic. There are many fuzzy logic with different semantic. So the question is "why those functions and not others?" The answer is because the semantic of every fuzzy logic must behave, for assignment in {0,1} as classical propositional logic.

Even Godel logic satisfy the principle of truth-functionality so the value of \mu (\alpha (X_{1},...,X_{n})) depends only from the values assigned to X_{1},...,X_{n}.

Exercise. Let \mu :FORM\to \{0,1\}. Prove that the semantic of Goedel logic coincide with semantic of classical propositional logic for the formulas \bot ,\top ,\neg \alpha ,\alpha \land \beta ,\alpha \lor \beta ,\alpha \to \beta .

Exercise. let \alpha ,\beta \in FORM. Prove that

  1. \mu (\neg \alpha ))=\mu (\alpha \to \bot )\forall \mu :FORM\to [0,1]
    The negation is semantically definable from implication and "falsum" (\bot ).
  2. \mu (\alpha \leftrightarrow \beta )=1 if and only if \mu (\alpha )=\mu (\beta )

Exercise. Make a plot of every function of Goedel logic. (Some are in 3D).
Here's the graph of \mu (\alpha \land \beta ) graph

It is important to said that evary fuzzy logic assign \mu (\alpha \to \beta )=1 when \mu (\alpha )\leq \mu (\beta ) infact, without this, MP wouldn't preserve tautology in fuzzy logic and it would be impossible to prove the theorem of completeness in that fuzzy logic.

Definition (truth, not truth, falsehood). Let \alpha \in FORM and \mu :FORM\to [0,1]. When we have \mu (\alpha )=1 we say that \alpha is true in the interpretation of \mu , or \mu is a model of \alpha . Instead, when we have \mu (\alpha )<1 we say that \alpha is not true in the interpretation of \mu .
In particular we say that \alpha is false in the interpretation of \mu when we have \mu (\alpha )=0. In symbols:
\mu \models _{g}\alpha when \mu (\alpha )=1
\mu \not \models _{g}\alpha when \mu (\alpha )<1.
When \alpha is true for every \mu we say that \alpha is a tautology. Instead when we have \alpha false for every assignment \mu we say that \alpha is a contradiction. When exists a \mu such as \mu (\alpha )=1 we say that \alpha is satisfiable; instead when exists a \mu such as \mu (\alpha )<1 we say that \alpha is refutable.
In symbols:
\models _{g}\alpha tautology
\not \models _{g}\alpha refutable

Exercise. Establish which of the following formulas are tautology in Godel Logic and which not.

  1. \alpha \lor \neg \alpha (Excluded middle)
  2. \neg (\alpha \land \neg \alpha ) (Not contradiction)
  3. \neg \neg \alpha \leftrightarrow \alpha (Law of double negation)
  4. \neg (\alpha \land \beta )\leftrightarrow \neg \alpha \lor \neg \beta (De Morgan rule I)
  5. \neg (\alpha \lor \beta )\leftrightarrow \neg \alpha \land \neg \beta (De Morgan rule II)
  6. \alpha \land \neg \alpha \to \beta (Ex falso quodlibet)
  7. (\alpha \to \beta )\lor (\beta \to \alpha ) (Prelinearity)

For example: The law of Excluded middle is not a tautology in Godel Logic, infact for \mu (\alpha )=0.5 we have that \mu (\alpha \lor \neg \alpha )=0.5.

It is clear that the semantic of Godel logic is equal to classical logic only for boolean values of the variables. The exercise above shows that some tautology in classical logic aren't tautology in Godel logic. Summing up:

Proposition. If \alpha is a tautology is Godel logic then is a tautology \alpha is a tautology in classical logic, but the reverse isn't true.
\models _{g}\alpha \to \models \alpha
TAUT_{g}\subset TAUT
Exercise. Prove the above proposition. Here's my proof:
\alpha \in TAUT_{g}\leftrightarrow \forall \mu \in MU_{g}\quad \mu (\alpha )=1 where MU_{g} is the set of all the possibile \mu :FORM\to [0,1]
\alpha \in TAUT\leftrightarrow \forall \mu \in MU\quad \mu (\alpha )=1 where MU is the set of all the possibile \mu :FORM\to \{0,1\}
MU\subset MU_{g} so if the former is true, the latter is true too.

Relationship between syntax and semantic

Definition (Axioms of GL (Godel logic)). For all \alpha ,\beta ,\gamma \in FORM, let's consider the following formulas.

  1. \alpha \to (\beta \to \alpha )
  2. (\alpha \to \beta )\to ((\alpha \to (\beta \to \gamma ))\to (\alpha \to \gamma ))
  3. \alpha \to (\beta \to (\alpha \land \beta ))
  4. (\alpha \land \beta )\to \alpha
  5. (\alpha \land \beta )\to \beta
  6. (\alpha \to (\alpha \land \beta ))
  7. (\alpha \to (\alpha \land \beta ))
  8. (\alpha \to \gamma )\to ((\beta \to \gamma )\to ((\alpha \lor \beta )\to \gamma ))
  9. (\alpha \to \beta )\to ((\alpha \to \neg \beta )\to \neg \alpha )
  10. \alpha \to (\neg \alpha \to \beta )

The formulas between 1 and 10 \in AXIOM_{g}\subset FORM.
AXIOM_{g} is called set of the axioms of Godel logic.
AXIOM_{g}\subset AXIOM.

Theorem of validity and completeness. For all \alpha \in FORM we have
\vdash _{g}\alpha \leftrightarrow \models _{g}\alpha

The demonstrable formulas coincide with tautologies also in Godel Logic. The demonstration of validity theorem is equal to that of classical logic.
Exercise. Prove that modus ponens preserves tautology in Godel Logic.