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Approximation Algorithms Department of Mathematics and Computer Science Drexel University.

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1 Approximation Algorithms Department of Mathematics and Computer Science Drexel University

2 Primal-Dual Method:  Remember from last lecture the weighted vertex-cover problem: Given: G=(V,E) and, weights w 1,…,w n on V Task: Find a subset of vertices S satisfying: subject to:

3 LP Relaxation  We saw an algorithm [Hochbaum] that converted Vertex Cover to an Integer Programming (IP) problem, relaxed the IP to a linear programming (LP) problem, and then used rounding to convert the LP solution back to integers:

4 Example  To round, we take the optimal LP solution, x*, and choose as our solution to the vertex cover  But this approach has two problems. First, solving the LP is expensive, so we'd like to find something cheaper. Second, for some algorithms rounding may not work as a method for converting the LP optimum back into an integer solution that has provably good approximation bounds.  The Primal­Dual method is a technique that can be used across a broad class of problems to quickly find an integer solution with provable approximation bounds.

5 Dual LP:  For any LP there is a dual LP:

6 For example:  The Primal-Dual pair for weighted vertex- cover will be:

7 Little more about LP:  Given a LP, a point x is said to be feasible if it satisfies all the constraints.  LPs can be classified according to their set of feasible solutions: Feasible: if a feasible solution exists:  Bounded: if a minimum exists  Unbounded: if we can find feasible solutions of arbitrary small values Infeasible: if the set of feasible solutions is empty.

8 Important Theorem!  For a linear system Ax=b, exactly one of the following holds: Either Or

9 Farkas Lemma  For any system of inequalities Ax=b, x>=0, exactly one of the following holds: Either Or

10 Back to Primal Dual Pair  For the primal dual pair  Let x* denote the optimal solution of primal, and let y be a feasible solution for dual, then Where the inequality follows since x*>=0.  So the dual problem finds the best possible lower bound for primal!

11 Weak Duality  Given feasible solutions x and y to the primal and dual problems, then  In particular,

12 Poof:  Given any solution x and y to the primal and dual respectively, we have:  So,  Likewise,  Implying:  Finally, adding the two inequalities we will have

13 For the WVC:

14 In fact (strong duality):  If a linear programming problem has an optimal solution x*, then its dual has an optimal solution y*, and

15 Primal-Dual Method for WVC  Instead of solving the LP or its Dual optimally something slightly different will be done. Construct A vertex cover (i.e. an integral solution to the LP). A feasible solution to the Dual. (But not necessarily an optimal solution). such that

16 Algorithm

17 Observe that:  x is vertex cover.  y is dual feasible.  We have: At each step we kept the constraints tight But for each i, x i =0 or 1:

18 The Generalized Steiner Tree Problem :  We are given a graph G=(V,E) with edge weights and a set of vertices selected out of V say pairs s i, t i such that s i and t i need to communicate. We'd like to find a minimum cost sub-graph such that all the pairs are connected.  Given: G=(V,E) w.l.o.g. fully connected, weights w e >= 0, for every edge e in E,,…, pairs of communicating edges  Find: A min­cost sub-graph H of G such that for all values of i in {1,…,k} the pairs ’s are connected in H.

19 Two Definitions:  Define L(S) as the indicator of subset S of V if S forms a cut that separates one of the pairs. More formally:  Also, for a graph G=(V,E) and a subset of vertices S define d (S)={(i, j) in E: i in S and j not in S}. That is, d (S) is the set of edges that cross the cut boundary.

20 ILP Formulations:

21 Relaxation:  We will relax the integrality condition to x e >=0. As a result:

22 Dual Problem:

23 Primal-dual Algorithm:  Initialization:  We will start with each vertex in its connected component. Then we will grow little balls around the components which disconnected communicators. When two balls merge, their connected components will be merged, add the edge between them, continue!

24 The algorithm

25 Example:  Communicating pairs:,.

26 Correctness  Given a Steiner tree problem, the above algorithm gives a feasible solution H and a feasible LP dual solution y such that:

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