# Nice resource roadmap [tutorials, textbooks, a good blog] for a non-CS major to understand clearly P vs NP? [closed]

What is the correct resource roadmap [tutorials, textbooks, a good blog post] for a non-CS major (with some programming experience in C++ and python) to understand clearly P, NP and algorithmic complexity? I followed some links on the web but it is quite difficult to grasp the huge number of definitions(deterministic turing machine, non deterministic turing machine, etc). P.S: My head is spinning trying to grasp what is a non-deterministic turing machine.

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## closed as off-topic by delnan, Phpdevpad, Alvin Wong, Dukeling, FrankOct 1 '13 at 16:41

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Sorry, this is off topic (resource requests in general are, as they are effectively opinion-based and don't have one correct answer) and you won't really understand the two complexity classes without understanding the concepts they are built on (such as det. and non-det. TM). There are simplified explanations, including some answers to other questions on this site, but in the end those are just that - simplifications, good to get started and get some intuition, but not nearly rigorous enough. – delnan Sep 26 '13 at 9:50

Ok, I will try to explain it as simple as I can,

First of just to make it clear P is Polynomial and NP is Nondeterministic Polynomial (not non-polynomial, this is a common mistake).

Now the nondeterministic term refers to a nondeterministic turing machine, so it can manage nondeterministic situation (from one state you can move to more than one state).

The important thing here is that in NP problems we can verify the output in polynomial time.

Now the thing you need to know is that the P class is contained in the NP class.

So the NP is bigger, and it also contains a particular subclass called NP-complete, here I wont go to far, I will just say that they are the most difficult of the NP problems. And that they are all connected, so if we solve efficiently one of them then we can solve efficiently all of the NP-complete, and thus all NP (since NP-complete are the hardest of NP).

The only problem is that in Computer Science there is still now proof of the relation between P and NP-complete. So there is no proof that NP-complete can not be polynomial neither the opposite. This one of the most important problems in complexity.

Anyways, if you need more details in any of things I just told you, just comment.

Regards

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Thanks a lot @luiso1979. Some sub-questions 'in NP problems we can verify the output in polynomial time.' So now you assume that there exists an algorithm which gives you an output to the problem. right? 'P is contained in NP' because if we can verify the output for an NP-problem in polynomial time, it means that output was also obtained in polynomial time.? you see the confusion? – hAcKnRoCk Sep 26 '13 at 10:44
No problem at all. Yes, of course, putting it simple, all NP problems are solvable via algorithm. Regarding the second question, Not at all, P are solvable in Polynomial time (and also verifiable), but in NP there are problems that don´t have a polynomial algorithm (or at least not yet). The important thing is that all NP are verifiable in Polynomial time, and P can also be solved in polynomial time. See the difference? – luiso1979 Sep 26 '13 at 11:08
Ahh btw, if you like my answer vote me up, pleeeease ;) – luiso1979 Sep 26 '13 at 11:08
This article was very eye-opening: newyorker.com/online/blogs/elements/2013/05/… – hAcKnRoCk Sep 26 '13 at 12:03
yes i see the difference.thanks and i upvoted your comment as well. – hAcKnRoCk Sep 28 '13 at 10:17