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Using DeMorgans I get:

~~(abc)  // ~ is the not.

My problem is when I try to build the circuit the NAND gate takes only 2 inputs. So how would I split it for 3? If it was an AND gate I would just use two and the equation would be:

(a AND b) AND c

However, this will not work with my NAND, since

~((a NAND b) NAND c) != (abc)
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2 Answers 2

If all you want is a circuit which outputs 0 when all inputs are 1...

You can simply check if any of them are 0, then negate that.

You already said the answer: De Morgan's laws. Just apply them: ~(a^b^c) = ~a or ~b or ~c

Though maybe I missed something. Are there other restrictions I might not have picked up on?

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I want to use NAND only. I read somewhere CPU has only NAND gates. Eitherway, I only want to use NANDs. –  Robert Mac Feb 14 '13 at 2:29
    
I think what you ready might have been that a cpu CAN be made using only NAND gates and tricky wiring. Give me a minute to sketch up how this would be accomplished using NAND only –  amarunowski Feb 14 '13 at 2:33
    
So, keep in mind that you can connect 'a' to both inputs on a NAND gate and get an inverter (or a "not gate"). If you do that, you can easily make an or gate out of 3 NAND gates. –  amarunowski Feb 14 '13 at 2:41
    
Was this helpful? –  amarunowski Feb 14 '13 at 3:40

Do the 2 ~'s mean you want to NOT the output twice? If so, ~~(abc) = (abc), (the two NOT's cancel each other out) so you can just do (a AND b) AND c.

If you want to just take the NOT of (abc) once, you can first do (a AND b) AND c, and then you can pass that output through an inverter. You would need two chips instead of one.

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