Please, help me make equivalent transformations with this formula (A∨C→B)(A→C)(¬B→¬A∧C)(¬A→(C→B))(B→¬C→¬A). Thanks.
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3This doesn't make sense. – Git Gud Jun 04 '14 at 21:59
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I must make as here, only with my formula http://minus.com/i/s3dtb4Vh0FCL – Maxikkk Jun 05 '14 at 08:30
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oh... I'm stupid. Sorry, of course (A+C→B)(A→C)(¬B→¬A∧C)(¬A→(C→B))(B→¬C→¬A). Thank you. – Maxikkk Jun 05 '14 at 09:10
1 Answers
You cannot "mix" in this way different "conventions" regarding symbols.
If you want to use propositional connectives (like : $\lor, \land$) instead of boolean operators (like : $\cdot, +$) you have to rewrite your formula with $\lor$ in place of $+$ and $\land$ in place of $\cdot$ (justaxposition).
If so, I think that your formula must be :
$((A∨C)→B) \land (A→C) \land (¬B→(¬A \land C)) \land (¬A→(C→B)) \land (B→(¬C→¬A))$
having restored some missing parentheses.
Then we eliminate $\rightarrow$, through the equivalence between $P \rightarrow Q$ and $\lnot P \lor Q$.
In this way, splitting the problem, we have five conjuncts to consider:
(i) $((A∨C)→B)$ is : $\lnot (A∨C) \lor B$ which, by De Morgan, is : $(\lnot A \land \lnot C) \lor B$, which in turn is equivalent to : $(\lnot A \lor B) \land (B \lor \lnot C)$, by distributivity.
In boolean form is : $(\bar {A} + B)(B + \bar {C})$.
(ii) $(A→C)$ is simply : $(\lnot A \lor C)$. In boolean : $(\bar {A} + C)$.
(iii) $(¬B→(¬A \land C))$ is : $B \lor (\lnot A \land C)$, using double negation, which in turn is equivalent to : $(\lnot A \lor B) \land (B \lor C)$, by distributivity.
In boolean form is : $(\bar {A} + B)(B + C)$.
(iv) $(¬A→(C→B))$ is : $A \lor (\lnot C \lor B)$. In boolean : $(A + B + \bar {C})$.
(v) $(B→(¬C→¬A))$ is : $\lnot B \lor (C \lor \lnot A)$. In boolean : $(\bar {A} + \bar {B} + C)$.
Now, we can "reassemble" the conjuncts (i) to (v) without redundant terms :
$(\bar {A} + B)(B + \bar {C})(\bar {A} + C)(B + C)(A + B + \bar {C})(\bar {A} + \bar {B} + C)$.
Now we start with boolean simplification, "inserting" the missing terms [i.e. : $(\bar {A} + B)$ is rewritten as : $(\bar {A} + B + C\bar {C})$ i.e. $(\bar {A} + B + C)(\bar {A} + B + \bar {C})$ ] :
$(\bar {A} + B + C)(\bar {A} + B + \bar {C})(A + B + \bar {C})(\bar{A} + B + \bar {C})(\bar {A} + B + C)(\bar {A} + \bar {B} + C)(A + B + C)(\bar {A} + B + C)(A + B + \bar {C})(\bar {A} + \bar {B} + C)$
and cancel the redundant terms :
$(\bar {A} + B + C)(\bar {A} + B + \bar {C})(A + B + \bar {C})(\bar {A} + \bar {B} + C)(A + B + C)$.
This is the standard Product-of-Sums (POS) Form.
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