To Close Is Easier Than To Open: Dual Parameterization To k-Median

The $k$-Median problem is one of the well-known optimization problems that formalize the task of data clustering. Here, we are given sets of facilities $F$ and clients $C$, and the goal is to open $k$ facilities from the set $F$, which provides the best division into clusters, that is, the sum of distances from each client to the closest open facility is minimized. In the Capacitated $k$-Median, the facilities are also assigned capacities specifying how many clients can be served by each facility. Both problems have been extensively studied from the perspective of approximation algorithms. Recently, several surprising results have come from the area of parameterized complexity, which provided better approximation factors via algorithms with running times of the form $f(k)\cdot poly(n)$. In this work, we extend this line of research by studying a different choice of parameterization. We consider the parameter $\ell = |F| - k$, that is, the number of facilities that remain closed. It turns out that such a parameterization reveals yet another behavior of $k$-Median. We observe that the problem is W[1]-hard but it admits a parameterized approximation scheme. Namely, we present an algorithm with running time $2^{O(\ell\log(\ell/\epsilon))}\cdot poly(n)$ that achieves a $(1+\epsilon)$-approximation. On the other hand, we show that under the assumption of Gap Exponential Time Hypothesis, one cannot extend this result to the capacitated version of the problem.

[1]  Jaroslaw Byrka,et al.  Constant factor FPT approximation for capacitated k-median , 2018, ESA.

[2]  Johan M. M. van Rooij Exact Exponential-Time Algorithms for Domination Problems in Graphs , 2011 .

[3]  Jason Li,et al.  On the Fixed-Parameter Tractability of Capacitated Clustering , 2022, ICALP.

[4]  Sudipto Guha,et al.  A constant-factor approximation algorithm for the k-median problem (extended abstract) , 1999, STOC '99.

[5]  Jaroslaw Byrka,et al.  An approximation algorithm for Uniform Capacitated k-Median problem with 1 + ε capacity violation , 2015, ArXiv.

[6]  Shi Li On Uniform Capacitated k-Median Beyond the Natural LP Relaxation , 2015, SODA.

[7]  Rajmohan Rajaraman,et al.  Analysis of a local search heuristic for facility location problems , 2000, SODA '98.

[8]  Henning Fernau,et al.  NONBLOCKER: Parameterized Algorithmics for minimum dominating set , 2006, SOFSEM.

[9]  Shi Li,et al.  Approximating capacitated k-median with (1 + ∊)k open facilities , 2014, SODA.

[10]  Rajesh Chitnis,et al.  A Tight Lower Bound for Planar Steiner Orientation , 2019, Algorithmica.

[11]  Pasin Manurangsi,et al.  Parameterized Approximation Algorithms for Directed Steiner Network Problems , 2017, ESA.

[12]  Fahad Panolan,et al.  Lossy kernelization , 2016, STOC.

[13]  Samir Khuller,et al.  Greedy strikes back: improved facility location algorithms , 1998, SODA '98.

[14]  Irit Dinur,et al.  Mildly exponential reduction from gap 3SAT to polynomial-gap label-cover , 2016, Electron. Colloquium Comput. Complex..

[15]  Amit Kumar,et al.  Tight FPT Approximations for $k$-Median and k-Means , 2019, ICALP.

[16]  Pasin Manurangsi,et al.  Parameterized Intractability of Even Set and Shortest Vector Problem from Gap-ETH , 2018, Electron. Colloquium Comput. Complex..

[17]  Luca Trevisan,et al.  From Gap-ETH to FPT-Inapproximability: Clique, Dominating Set, and More , 2017, 2017 IEEE 58th Annual Symposium on Foundations of Computer Science (FOCS).

[18]  Jaroslaw Byrka,et al.  An Approximation Algorithm for Uniform Capacitated k-Median Problem with 1+\epsilon Capacity Violation , 2015, IPCO.

[19]  Prasad Raghavendra,et al.  A Birthday Repetition Theorem and Complexity of Approximating Dense CSPs , 2016, ICALP.

[20]  Rolf H. Möhring,et al.  A constant FPT approximation algorithm for hard-capacitated k-means , 2019 .

[21]  Anupam Gupta,et al.  An FPT Algorithm Beating 2-Approximation for k-Cut , 2017, SODA.

[22]  Satish Rao,et al.  A tight bound on approximating arbitrary metrics by tree metrics , 2003, STOC '03.

[23]  Mam Riess Jones Color Coding , 1962, Human factors.

[24]  Saket Saurabh,et al.  Parameterized Complexity and Approximability of Directed Odd Cycle Transversal , 2017, SODA.

[25]  Michal Pilipczuk,et al.  Parameterized Algorithms , 2015, Springer International Publishing.

[26]  Sudipto Guha,et al.  Rounding via Trees : Deterministic Approximation Algorithms forGroup , 1998 .

[27]  Shi Li,et al.  Constant Approximation for Capacitated k-Median with (1+epsilon)-Capacity Violation , 2016, ICALP.

[28]  Pasin Manurangsi,et al.  A Survey on Approximation in Parameterized Complexity: Hardness and Algorithms , 2020, Electron. Colloquium Comput. Complex..

[29]  Shi Li,et al.  On Uniform Capacitated k-Median Beyond the Natural LP Relaxation , 2014, SODA.

[30]  Kamesh Munagala,et al.  Local Search Heuristics for k-Median and Facility Location Problems , 2004, SIAM J. Comput..

[31]  Pasin Manurangsi Tight Running Time Lower Bounds for Strong Inapproximability of Maximum k-Coverage, Unique Set Cover and Related Problems (via t-Wise Agreement Testing Theorem) , 2020, SODA.

[32]  Aravind Srinivasan,et al.  An Improved Approximation for k-Median and Positive Correlation in Budgeted Optimization , 2014, SODA.

[33]  Shi Li,et al.  Constant Approximation for Capacitated k-Median with (1 + ε)-Capacity Violation , 2016, ArXiv.

[34]  Samir Khuller,et al.  LP Rounding for k-Centers with Non-uniform Hard Capacities , 2012, 2012 IEEE 53rd Annual Symposium on Foundations of Computer Science.