On the Approximability of the Multi-dimensional Euclidean TSP

Luca Trevisan

Electronic Colloquium on Computational Complexity

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Revision #1 to TR96-046 | 14th November 1996 00:00

When Euclid Meets Hamming: the Approximability of Geometric TSP and MST Revision of: TR96-046

Revision #1 Authors: Luca Trevisan
Accepted on: 14th November 1996 00:00
Downloads: 3329

Keywords:

Approximation Algorithms, complexity theory, EuclidSpaces, Hamming Spaces, Max SNP-hardness, Steiner Tree Problem, Traveling Salesman Problem

Abstract:

We prove that the Traveling Salesperson Problem (TSP),
the Minimum Steiner Tree Problem (MST), the Minimum
k-Steiner Tree problem (MkST) and the k-Center Problem
are MAXSNP-hard (and thus NP-hard to approximate within
some constant r > 1) even if all cities (respectively,
points) lie in the geometric space $R^n$ (n is
the number of cities/points) and distances are computed
with respect to the $l_1$ (rectilinear) metric.
The TSP and k-Center hardness results also hold for any $l_p$
metric, including the Euclidean $\ell_2$ metric, and
(under randomized reductions) also in $\rea^{\log n}$ for the
Euclidean metric.
Arora's approximation scheme for Euclidean TSP in $\rea^d$ runs
in time $n^{\tilde O(\log^{d-2} n)/\epsilon^{d-1}}$ and
achieves approximation $(1+\epsilon)$; our result implies
that this running time cannot be improved to $n^{d/\epsilon}$
unless NP has subexponential randomized algorithms. We also prove,
as an intermediate step, the hardness of approximating the above
problems in Hamming spaces. The only previous hardness
results involved metrics where all distances are 1 or 2.

Paper:

TR96-046 | 27th August 1996 00:00

On the Approximability of the Multi-dimensional Euclidean TSP

TR96-046 Authors: Luca Trevisan
Publication: 30th August 1996 17:11
Downloads: 1886

Keywords:

Approximation Algorithms, complexity theory, Euclidean Spaces, Max SNP-hardness, Traveling Salesman Problem

Abstract:

We consider the Traveling Salesperson Problem (TSP) restricted
to Euclidean spaces of dimension at most k(n), where n is the number of
cities. We are interested in the relation between the asymptotic growth of
k(n) and the approximability of the problem. We show that the problem is
Max SNP-hard when k(n) = n-1. Thus, for a certain constant e1>0, the
(n-1)-dimensional Euclidean TSP cannot be approximated within a factor
(1+e1) in polynomial time, unless P=NP. Using a previous result about
embedding of Euclidean metrics in low-dimensional spaces, we can also prove
that constants c and e2 exist such that approximating the
(c log n)-dimensional Euclidean TSP within 1+e2 is NP-hard under randomized
reductions (and thus not solvable in P, unless RP=NP). This contrasts with
a recent result by Arora who presented a polynomial time approximation
scheme for the bidimensional Euclidean TSP. Additionally, we note
extensions of our result to other geometric metrics.

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