How to find “if Q then S” in this classic CSL derivation [closed]

Here's the problem: I have to derive Q>S from:

1. (P^Q^R)>S
2. (~P^Q^~R)>S

I'm not allowed to use any derived rules or replacement rules (De Morgan's, implication, Modus Tolluns etc), only classic logic rules. I have tried everything I can think of and still cannot manage to get to the answer I need.

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Interesting, but not [exactly] SO-material... I do want to see where it goes though ;-) A suspect a "homework" tag is appropriate at the very least? –  user166390 Oct 26 '11 at 0:12
done, sorry, I didn't know I should do that! I wasn't sure if this was the place to post questions about CSL, but I'm a little desperate and hoping some capable person can save me. –  Allison Rand Oct 26 '11 at 0:18
It seems so obvious that what you have is ( (P^~P) ^ Q ^ (R^~R) ) > S and of course the "P or Not-P" is simply eliminated, but sorry, I can no longer recall the formal steps to get there. –  Stephen P Oct 26 '11 at 0:56
This question appears to be off-topic because it is about mathematical logic, which is more appropriate at math.stackexchange.com. –  templatetypedef Oct 24 '13 at 8:50

closed as off-topic by templatetypedef, M42, rcs, Ahmed Siouani, Adam SpiersOct 24 '13 at 10:42

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The reason that you cannot prove it is because it is not true.

Consider:

IF P and Q are true and R and S are false,

THEN:      < T   T    F     F >
1. ( P & Q &  R) -> S  is true     ( because "(False) -> False" is valid )
and    2. (~P & Q & ~R) -> S  is true     ( also because "(False) -> False" )

BUT:             Q       -> S  is NOT true ( because "True -> False" is invalid )


Therefore it cannot be possible to (validly) derive Q->S from your statements 1 and 2, even if you could use all of the derived rules, replacement, etc.

Pretty hard to prove something that's not true. (In logic anyway :)

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