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I am trying to understand the difference between NP-Complete and NP-Hard.

Below is my understanding

An NP-Hard problem is one that is not solvable in polynomial time but can be verified in polynomial time.
An NP-Complete problem is one that is in NP and is also NP-Hard.

Is the above definition correct? If so, What about problems not In NP but NP-Hard. Wouldn't they be harder than NP-Complete problem, say they can only be solved and verified in exponential time?

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it is unknown (and worth 1 million dollars) if NP complete problems can be solved in polynomial time. –  Rob Neuhaus Dec 11 '13 at 15:48

3 Answers 3

NP-Hard is lower bound on the problem. Impossible problems are also NP-Hard. NP-Complete means that it is NP-Hard and at the same time NP-Solvable.

Problems that can be verified in polynomial time is one of the definitions of problems in NP.

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Somehow you don't explain what NP-hard is, but then you define NPC as the intersection between NP-hard and NP? There's certainly something missing there –  Niklas B. Mar 19 at 3:46

An NP problem(not NP-Hard problem) is decision problem one that can be verified in polynomial time. Maybe they are solvable in polynomial time, since all problem in P are all in NP.

NP-complete is decision problem, which all NP problems can transformed into in polynomial time. They are the hardest problems in the class of NP.

NP-hard is the class of the problems which are at least as hard as NP-complete problem. There are not necessarily decision problem. It would be hard to say whether we can verify a NP-hard problem in polinomial time.

For example, the decision problem of maximum clique(Give an integer K, to tell whether there is a complete graph with at least K vertices ) is NP problem. It is also NP-complete and NP-hard. However, maximum clique problem(Find the maximum clique in a given Graph) is not NP or NP-complete, since it is not decision problem. We can say it is NP-hard, since it is at least as hard as the decision version of maximum clique problem.

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Your definition is only correct for NP-complete.

Starting from the bottom: P is the class of problems that can be solved by some deterministic Turing machine in polynomial time. NP is the class of problems that can be solved by some non-deterministic Turing machine in polynomial time (or whose solutions can be verified by deterministic Turing machines in polynomial time).

As for NP-hard, it means decision problems X that have the following property: given a Turing machine that solves the problem, one could restructure (Turing reduction) any instance of a problem in NP to an instance of X in polynomial time. Informally, this means that NP-hard problems are those that are "at least as hard as NP", or that the solution for X could be applied to every problem in NP. Note that the problem doesn't have to be verifiable in polynomial time, or actually verifiable at all. NP-hard includes undecidable and unrecognizable problems as well.

We don't know if NP-hard includes problems that can be solved in polynomial time or not (the P ?= NP problem). Currently, not a single polynomial-time solution for a NP-hard problem has been found, but neither has it been proven that such solution can't exist. If such a solution was found for some NP-hard problem X, that would mean P = NP as any instance of any problem in NP could be converted to an instance of X in polynomial time (because of the Turing reduction property of NP-hard problems) and then be solved in polynomial time by X's polynomial time solution.

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