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# Proving that P <= NP

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
@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

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
Define "obviously". I think that there's also need (or would be more interesting in practice) to provide a proof that uses that fact that solutions to NP problems can be verified in polynomial time. The main advantage of solving the problem P vs NP would be to be able or not to find solutions to NP problems that run in polynomial time or just being able to check them in polynomial time. The non-deterministic model is unreal for now. – nbro Aug 25 '15 at 14:56

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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