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As most people know, P = NP is unproven and seems unlikely to be true. The proof would prove that P <= NP and NP <= P. Only one of those is hard, though.

P <= NP is almost by definition true. In fact, that's the only way that I know how to state that P <= NP. It's just intuitive. How would you prove that P <= NP?

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@Travis how so? If you can solve a problem in polynomial time (belongs to P), you can DEFINITELY verify it in polynomial time (belongs to NP). The converse is not true. –  Gail Apr 14 '10 at 17:24
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@Nick that is the point. P is a subset of NP, so P is contained in NP. The statement is that NP is larger (or at least equal) to P, but P is completely contained within NP. –  Gail Apr 14 '10 at 17:31
    
possible duplicate of stackoverflow.com/questions/1870955/does-p-equal-np –  voyager Apr 14 '10 at 17:33
    
@Travis no.. If we can verify a solution in polynomial time, that puts it in the class NP. –  Gail Apr 14 '10 at 17:35
    
@Travis, P is by definition <= NP. Any problem which can be solved on a TM in polynomial time can be solved on an NTM in polynomial time. This is true because all TMs are NTMs. Furthermore, being able to verify a solution in polynomial time is the definition of a problem being in NP. –  Nick Lewis Apr 14 '10 at 17:40

4 Answers 4

up vote 11 down vote accepted

I think you've essentially answered your own question in the comments: a problem which satisfies the definition of P also satisfies the definition of NP.

To quote wikipedia:

All problems in P [are in NP] (For, given a certificate for a problem in P, we can ignore the certificate and just solve the problem in polynomial time. Alternatively, note that a deterministic Turing machine is also trivially a non-deterministic Turing machine that just happens to not use any non-determinism.)

The certificate it refers to is the polynomial-time verification of solution; as you say, you can solve a problem in P in polynomial time and you will therefore have a solution which has been verified in polynomial time and is therefore in NP.

Joey Adams' answer is the second explanation, in terms of solvability by (non)deterministic Turing machines. See the wikipedia article for a bit more explanation of that definition of NP.

I think what you should note here is that the fact that the proof is trivially simple doesn't mean it's not a proof. "By definition" is a perfectly valid logical step.

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Each problem in NP is solved by a nondeterministic Turing machine [in polynomial time]. (by definition*)

Each problem in P is solved by a deterministic Turing machine [in polynomial time]. (by definition)

Each deterministic Turing machine is a nondeterministic Turing machine as well. (obviously)

Hence each problem in P is solved by a nondeterministic Turing machine [in polynomial time].

Hence each problem in P is a problem in NP. Hence P ⊆ NP.


*Let's read Wikipedia article on NP:

In an equivalent formal definition, NP is the set of decision problems solvable in polynomial time by a non-deterministic Turing machine.

There's no need to introduce this stuff about polynomial verification into such a simple reasoning.

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+1, though I'm not sure if one definition is really that much simpler than the other - one could also say there's no need to introduce stuff about determinism into reasoning as simple as polynomial time solving/verification. –  Jefromi Apr 14 '10 at 18:25
    
@Jefromi, for this particular question it is simplier. And for some other questions, perhaps, it's simplier as well. One should not forget that there are several equivalent definition. –  Pavel Shved Apr 14 '10 at 18:27
    
The equivalence of the definitions was the main thing I was trying to emphasize, along with the fact that "simpler" is a bit subjective. –  Jefromi Apr 14 '10 at 19:01

A nondeterministic computer can simply not invoke its nondeterminism and act like a deterministic one, thus it can run P problems in polynomial time. That's the best answer I can think of.

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A non-deterministic computer that solves a (NP) problem in polynomial time would also solve a P problem in polynomial time.

If we consider the imaginary approach of a Turing Machine that can take several paths at a decision to solve the NP problem in polynomial time, this behaviour must be enough to solve the P problem in P Time. Deterministic Turing machines are a case of simple (real) non-deterministic machines.

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