computational complexity theory In theoretical computer science and mathematics, computational complexity theory focuses on classifying computational problems according to their resource usage, and relating these classes to each other. A computational problem is a task solved ...

, NP-hardness ( non-deterministic polynomial-time hardness) is the defining property of a class of problems that are informally "at least as hard as the hardest problems in NP". A simple example of an NP-hard problem is the subset sum problem. A more precise specification is: a problem ''H'' is NP-hard when every problem ''L'' in NP can be reduced in polynomial time to ''H''; that is, assuming a solution for ''H'' takes 1 unit time, ''H''s solution can be used to solve ''L'' in polynomial time. As a consequence, finding a polynomial time algorithm to solve any NP-hard problem would give polynomial time algorithms for all the problems in NP. As it is suspected that P≠NP, it is unlikely that such an algorithm exists. It is suspected that there are no polynomial-time algorithms for NP-hard problems, but that has not been proven. Moreover, the class P, in which all problems can be solved in polynomial time, is contained in the NP class.

Definition

decision problem In computability theory and computational complexity theory, a decision problem is a computational problem that can be posed as a yes–no question of the input values. An example of a decision problem is deciding by means of an algorithm whe ...

''H'' is NP-hard when for every problem ''L'' in NP, there is a

polynomial-time many-one reduction In computational complexity theory, a polynomial-time reduction is a method for solving one problem using another. One shows that if a hypothetical subroutine solving the second problem exists, then the first problem can be solved by transforming ...

from ''L'' to ''H''. An equivalent definition is to require that every problem ''L'' in NP can be solved in polynomial time by an oracle machine with an oracle for ''H''. Informally, an algorithm can be thought of that calls such an oracle machine as a subroutine for solving ''H'' and solves ''L'' in polynomial time if the subroutine call takes only one step to compute. Another definition is to require that there be a polynomial-time reduction from an NP-complete problem ''G'' to ''H''. As any problem ''L'' in NP reduces in polynomial time to ''G'', ''L'' reduces in turn to ''H'' in polynomial time so this new definition implies the previous one. Awkwardly, it does not restrict the class NP-hard to decision problems, and it also includes search problems or optimization problems.

Consequences

If P ≠ NP, then NP-hard problems could not be solved in polynomial time. Some NP-hard optimization problems can be polynomial-time approximated up to some constant approximation ratio (in particular, those in APX) or even up to any approximation ratio (those in PTAS or

FPTAS A fully polynomial-time approximation scheme (FPTAS) is an algorithm for finding approximate solutions to function problems, especially optimization problems. An FPTAS takes as input an instance of the problem and a parameter ε > 0. It ...

Examples

An example of an NP-hard problem is the decision subset sum problem: given a set of integers, does any non-empty subset of them add up to zero? That is a

and happens to be NP-complete. Another example of an NP-hard problem is the optimization problem of finding the least-cost cyclic route through all nodes of a weighted graph. This is commonly known as the travelling salesman problem. There are decision problems that are ''NP-hard'' but not ''NP-complete'' such as the

halting problem In computability theory, the halting problem is the problem of determining, from a description of an arbitrary computer program and an input, whether the program will finish running, or continue to run forever. Alan Turing proved in 1936 that a ...

. That is the problem which asks "given a program and its input, will it run forever?" That is a ''yes''/''no'' question and so is a decision problem. It is easy to prove that the halting problem is NP-hard but not NP-complete. For example, the

Boolean satisfiability problem In logic and computer science, the Boolean satisfiability problem (sometimes called propositional satisfiability problem and abbreviated SATISFIABILITY, SAT or B-SAT) is the problem of determining if there exists an interpretation that satisf ...

can be reduced to the halting problem by transforming it to the description of a

Turing machine A Turing machine is a mathematical model of computation describing an abstract machine that manipulates symbols on a strip of tape according to a table of rules. Despite the model's simplicity, it is capable of implementing any computer alg ...

that tries all

truth value In logic and mathematics, a truth value, sometimes called a logical value, is a value indicating the relation of a proposition to truth, which in classical logic has only two possible values ('' true'' or '' false''). Computing In some pro ...

assignments and when it finds one that satisfies the formula it halts and otherwise it goes into an infinite loop. It is also easy to see that the halting problem is not in ''NP'' since all problems in NP are decidable in a finite number of operations, but the halting problem, in general, is undecidable. There are also NP-hard problems that are neither ''NP-complete'' nor ''Undecidable''. For instance, the language of true quantified Boolean formulas is decidable in

polynomial space In computational complexity theory, PSPACE is the set of all decision problems that can be solved by a Turing machine using a polynomial amount of space. Formal definition If we denote by SPACE(''t''(''n'')), the set of all problems that can b ...

, but not in non-deterministic polynomial time (unless NP = PSPACE).More precisely, this language is PSPACE-complete; see, for example, .

NP-naming convention

NP-hard problems do not have to be elements of the complexity class NP. As NP plays a central role in computational complexity, it is used as the basis of several classes: ; NP: Class of computational decision problems for which any given ''yes''-solution can be verified as a solution in polynomial time by a deterministic Turing machine (or ''solvable'' by a ''non-deterministic'' Turing machine in polynomial time). ;NP-hard: Class of problems which are at least as hard as the hardest problems in NP. Problems that are NP-hard do not have to be elements of NP; indeed, they may not even be decidable. ; NP-complete: Class of decision problems which contains the hardest problems in NP. Each NP-complete problem has to be in NP. ; NP-easy: At most as hard as NP, but not necessarily in NP. ; NP-equivalent: Decision problems that are both NP-hard and NP-easy, but not necessarily in NP. ; NP-intermediate: If P and NP are different, then there exist decision problems in the region of NP that fall between P and the NP-complete problems. (If P and NP are the same class, then NP-intermediate problems do not exist because in this case every NP-complete problem would fall in P, and by definition, every problem in NP can be reduced to an NP-complete problem.)

Application areas

NP-hard problems are often tackled with rules-based languages in areas including: * Approximate computing * Configuration *

Cryptography Cryptography, or cryptology (from grc, , translit=kryptós "hidden, secret"; and ''graphein'', "to write", or '' -logia'', "study", respectively), is the practice and study of techniques for secure communication in the presence of adv ...

* Data mining * Decision support *

Phylogenetics In biology, phylogenetics (; from Greek φυλή/ φῦλον [] "tribe, clan, race", and wikt:γενετικός, γενετικός [] "origin, source, birth") is the study of the evolutionary history and relationships among or within groups ...

* Planning * Process monitoring and control * Rosters or schedules * Routing/vehicle routing * Scheduling

References

* {{DEFAULTSORT:Np-Hard Complexity classes