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As a follow-up from my old question here, I'm wondering more about the equivalence proof. Intuitively, NP has been described as the class of all problems which a solution certificate can be verified in polynomial time. Let's say we have a problem $K$ in NP and we have a certificate $c_e$ obtained externally that proves a YES or NO result for $x$.

From my understanding of the proof implications, if we have a NTM which solves $K$ in polynomial time, this implies that there exists a verifier for $K$ which takes any certificate and says whether that specific certificate is a valid "solution" for if $x$ results in YES/NO. The proof involves the fact that the NTM generates its own certificate $c_n$ which the verifier then uses, but this has nothing to do with $c_e$ from what I see. From my understanding, the verifier should take any arbitrary certificate (including $c_e$) and verifies that it indeed leads to the answer. But instead, the verifier uses only the certificate $c_n$ created by the NTM to verify whether $x$ results in YES/NO. In other words, the verifier isn't able to check any arbitrary certificate - it's only able to check the one created by the NTM.

To rephrase in case I'm not making sense – constructing a verifier, in my interpretation, means this verifier can take any certificate and check whether it's a proof for $x$. But the equivalence proof has the verifier take a specific certificate $c_n$ created by the NTM and only checks whether that is a valid proof for $x$. So what makes the verifier able to verify for any arbitrary certificate $c_e$?

I must be getting confused somewhere. Is there any point which labels my misunderstanding? I'd really like to fully grasp the intuition of the proof.

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A non-deterministic Turing machine has a special instruction that allows it to non-deterministically "guess" a bit. The list of bits guessed by the machine is sometimes called a certificate. You can imagine that the guessed bits are taken from an auxiliary tape, whose contents you can think of as a certificate.

Here is an example. Consider the problem SAT: the input is a formula, and wish to find out whether the formula is satisfiable. A non-deterministic Turing machine for this problem "guesses" an assignment, and then checks ("verifies") that it satisfies the given formula. Alternatively, the machine gets a certificate and verifies that it is a satisfying assignment for the input formula. This is exactly the same Turing machine, only the process of non-deterministic guessing is visualized as reading from an auxiliary input, which we think of as a certificate.

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  • $\begingroup$ Thank you Yuval - I think I understand this part, but I'm not quite sure about an arbitrary certificate. If the machine receives a certificate, let's say $c_e$, how does the proof of equivalence demonstrate this exactly? That's more where I'm confused. $\endgroup$
    – rb612
    Commented Jan 12, 2018 at 5:23
  • $\begingroup$ I'm not sure what you mean by an arbitrary certificate. The certificate just specifies the guesses of the machine. There is no freedom beyond that. $\endgroup$
    – Yuval Filmus
    Commented Jan 12, 2018 at 8:09
  • $\begingroup$ sorry, I should've been more clear with that. So going along with SAT, the verifier will take a boolean formula as input along with a certificate, which in this case would be a set of true/false values. Now there may be multple sets of true/false values that satisfy a boolean formula. So thus there's the possibility of multiple valid certificates for a satisfiable problem with a given input. Say that I come up with certificate $c_e$. I'm wondering how are we ensured that a verifier created from an NTM is able to verify my certificate? The NTM could possibly guess a different certificate. $\endgroup$
    – rb612
    Commented Jan 12, 2018 at 8:26
  • $\begingroup$ There's nothing wrong with having more than one valid certificate. There isn't any canonical valid certificate - all valid certificates have the same status. $\endgroup$
    – Yuval Filmus
    Commented Jan 12, 2018 at 8:28
  • $\begingroup$ So let's say I have an invalid certificate I present to the verifier. By the equivalence proof, we construct an NTM. NTM comes up with a correct certificate. Verifier uses that correct certificate created by the NTM to verify the solution. So even though I presented an invalid certificate, if the NTM finds a valid certificate, the verifier will accept. But shouldn't the verifier reject my invalid certificate? In other words, I don't see my (potentially invalid) certificate being used anywhere in the equivalence proof. $\endgroup$
    – rb612
    Commented Jan 12, 2018 at 8:31

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