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 ...

, a PTAS reduction is an

approximation-preserving reduction In computability theory and computational complexity theory, especially the study of approximation algorithms, an approximation-preserving reduction is an algorithm for transforming one optimization problem into another problem, such that the dist ...

that is often used to perform

reductions Reductions ( es, reducciones, also called ; , pl. ) were settlements created by Spanish rulers and Roman Catholic missionaries in Spanish America and the Spanish East Indies (the Philippines). In Portuguese-speaking Latin America, such re ...

between solutions to optimization problems. It preserves the property that a problem has a polynomial time approximation scheme (PTAS) and is used to define completeness for certain classes of optimization problems such as

APX In computational complexity theory, the class APX (an abbreviation of "approximable") is the set of NP optimization problems that allow polynomial-time approximation algorithms with approximation ratio bounded by a constant (or constant-factor ap ...

. Notationally, if there is a PTAS reduction from a problem A to a problem B, we write

\text \leq_ \text

. With ordinary polynomial-time many-one reductions, if we can describe a reduction from a problem A to a problem B, then any polynomial-time solution for B can be composed with that reduction to obtain a polynomial-time solution for the problem A. Similarly, our goal in defining PTAS reductions is so that given a PTAS reduction from an optimization problem A to a problem B, a PTAS for B can be composed with the reduction to obtain a PTAS for the problem A.

Definition

Formally, we define a PTAS reduction from A to B using three polynomial-time computable functions, ''f'', ''g'', and ''α'', with the following properties: * ''f'' maps instances of problem A to instances of problem B. * ''g'' takes an instance ''x'' of problem A, an approximate solution to the corresponding problem

f(x)

in B, and an error parameter ε and produces an approximate solution to ''x''. * ''α'' maps error parameters for solutions to instances of problem A to error parameters for solutions to problem B. * If the solution ''y'' to

f(x)

(an instance of problem B) is at most

1 + \alpha(\epsilon)

times worse than the optimal solution, then the corresponding solution

g(x,y,\epsilon)

to ''x'' (an instance of problem A) is at most

1 + \epsilon

times worse than the optimal solution.

Properties

From the definition it is straightforward to show that: *

\text \leq_ \text

and

\text \in \text \implies \text \in \text

\text \leq_ \text

and

\text \not\in \text \implies \text \not\in \text

L-reductions imply PTAS reductions. As a result, one may show the existence of a PTAS reduction via a L-reduction instead. PTAS reductions are used to define completeness in

, the class of optimization problems with constant-factor approximation algorithms.

References

* Ingo Wegener. Complexity Theory: Exploring the Limits of Efficient Algorithms. {{isbn, 3-540-21045-8. Chapter 8, pp. 110–111
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Reduction (complexity) Approximation algorithms

Definition

Properties

See also

References