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Chandra Chekuri, Nitish Korula and Martin Pal Proceedings of the nineteenth annual ACM-SIAM symposium on Discrete algorithms (SODA 08) Improved Algorithms for Orienteering and Related Problems Presented By: Asish Ghoshal
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The Problem Given a graph G(V,E) (directed or undirected), two nodes s,t V and a non-negative budget B, find an s-t walk of total length at most B so as to maximize the number of distinct nodes visited by the walk. A node may be visited multiple times by the walk but is only counted once in the objective function. Motivated from real world problems in vehicle routing, robot motion planning.
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Quick Facts Is NP-hard Is APX-hard (cannot be approximated within 1481/1480) Introduced in 1987 by Bruce L. Golden, Larry Levy, and Rakesh Vohra
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Introduction Orienteering belongs to the class of prize collecting TSP. Given a set of cities with some “prize” associated with each city and given a set of pair wise distances, a salesman needs to pick a subset of cities so as to minimize distance and maximize total reward. Bi-criteria optimization problem.
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Introduction General approach: Fix one criteria and optimize the other –K-TSP, k-Stroll Fix: No of nodes (total reward) Optimize: distance –Orienteering Fix: Total distance (budget) Optimize: Reward (no of nodes covered)
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The Story So far First non-trivial approximation: 2 + Ɛ (Arkin, Mitchell and Narasimhan) for points on Euclidean plane. 4 (Blum et al) for points on arbitrary metric spaces. 3 (Bansal et al) PTAS (K. Chen and Har-peled) for fixed dimensional Euclidean space.
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Results Undirected graphs: –Ratio of (2+δ) and running time of n O(1/ δ^2) Directed Graphs: Ratio O(log 2 OPT)
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Approach The basic approach: Approximation of k-stroll -> approximation of minimum excess -> approximation for Orienteering.
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The MIN_EXCESS Problem The excess of a path P is defined as the difference between the length of the path L and the shortest distance D between its end points. i.e excess(P) = L – D Given a weighted graph with rewards, end points s and t, and a reward quota k, find a minimum excess path from s to t collecting reward at least k.
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MIN_EXCESS (Contd) If x is the excess of an optimal path, an α- approximation for the minimum-excess problem has length at most: d(t) + αx ≤ α(d(t) + x) and hence gives an α approximation for the minimum length problem. Note: d(t) is the shortest distance between the end points of the path.
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K-stroll to Orienteering via min-excess 1.In undirected graphs a β-approximation to the k-stroll problem implies a (3 β/2 – ½)- approximation to the minimum excess problem (Blum 2003) 2.In directed graphs a β-approximation to the k- stroll problem implies a (2β - 1)-approximation to the minimum excess problem. 3.A γ-approximation to the min-excess problem implies a | γ| approximation for orienteering. (Bansal 2004)
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2 and 3 can be extended to show that an (α,β)-approximation to the k-stroll algorithm for directed graphs gives (α|2β - 1|)-approximation for directed orienteering. Using 1 and 3 and a (1 + δ,2)- approximation for the k-stroll problem gives a ((1+ δ)*|2.5|) = (3 + δ)- approximation for orienteering. But we are interested in (2 + δ) approximation. K-stroll to Orienteering via min-excess
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(2 + δ) approach Begin with k-stroll Given a metric graph G, with 2 specified vertices s, t and a target k, find an s-t path of minimum length that visits at least k vertices. Let L be the length of such an optimal path and D be the shortest path distance from s to t.
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(2 + δ) approach (Contd) Objective: For any fixed path that visits at least (1-O(δ))k vertices and has total length at most max{1.5D,2L-D}
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(Chaudhuri et al 2003) give a polynomial algorithm to find a tree T that spans k vertices containing both s and t, of length at most (1+ Ɛ )L for any Ɛ > 0 Guesses O(1/ Ɛ ) vertices s,w 1.. w m,t such that an optimal path P visits the vertices in the given order and length and distance between any w i -w i+1 is < Ɛ L. Assume all edges in T are < Ɛ L.
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Let P T s,t be the path in T from s to t. L is the shortest s-t path visiting k vertices. Since length(T)<= (1+ Ɛ )L We can double all edges of T not on P T s,t to obtain a path P T from s to t that visits k vertices. Length of P T is 2length(T)-length(P T s,t ) <= 2length(T) - D
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Easy Doubling conditions If length(T) <= 5D/4 then P T has length at most 3D/2). Length(P T s,t ) >= D+2 Ɛ L then length(P T ) <= 2(1+ Ɛ )L – (D + 2 Ɛ L) = 2L - D
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If the easy doubling conditions are not met it means D = (1/5 - 2 Ɛ )L Modify the tree T to T’ in the following way: Greedily decompose the edge set of T\P T s,t into Ω(1/δ) disjoint connected components, each with length in [δL,3δL) Merge connected components to get T’ Tree T’ contains a vertex of degree 1 or 2 that corresponds to a component containing at most 32δk vertices.
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Remove C C can either be a leaf or a node with degree 2 and contain at most 32δk vertices. So we get a tree T’’ of length (1-32δ)k vertices. If C is not a leaf we get two Trees. Find the shortest distance between trees. In either case double edges and we get a tree of length at most 2L-D and we are done.
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Conclusion Using results from Orienteering improved results can be obtained for TSP with deadlines and TSP with time windows.
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References N. Bansal, A. Blum, S. Chawla and A. Meyerson. Approximation Algorithms for Deadline TSP and Vehicle Routing with time windows. Proc. Of ACM STOC 166- 174. 2004 A.Blum, S.Chawla, D. Karger, T.Lane, A. Meyerson and M. Minkoff. Approximation algorithms for Orienteering and disounted reward TSP, SIAM J. On Computing, 37(2):653-670,2007. K. Chaudhuri, B.Godfrey, S.Rao and K.Talwar. Paths, trees and minimum latency tours. Proc. of IEEE FOCS, 36-45,2003.
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