Document Open Access Logo

Greedy Bipartite Matching in Random Type Poisson Arrival Model

Authors Allan Borodin, Christodoulos Karavasilis, Denis Pankratov

PDF
Thumbnail PDF

File

LIPIcs.APPROX-RANDOM.2018.5.pdf
  • Filesize: 0.65 MB
  • 15 pages

Document Identifiers

Author Details

Allan Borodin
  • University of Toronto, 10 Kings College Road, Toronto, Canada
Christodoulos Karavasilis
  • University of Toronto, 10 Kings College Road, Toronto, Canada
Denis Pankratov
  • University of Toronto, 10 Kings College Road, Toronto, Canada

Funding

Research is supported by NSERC.

Cite AsGet BibTex

Allan Borodin, Christodoulos Karavasilis, and Denis Pankratov. Greedy Bipartite Matching in Random Type Poisson Arrival Model. In Approximation, Randomization, and Combinatorial Optimization. Algorithms and Techniques (APPROX/RANDOM 2018). Leibniz International Proceedings in Informatics (LIPIcs), Volume 116, pp. 5:1-5:15, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2018)
https://doi.org/10.4230/LIPIcs.APPROX-RANDOM.2018.5

Abstract

We introduce a new random input model for bipartite matching which we call the Random Type Poisson Arrival Model. Just like in the known i.i.d. model (introduced by Feldman et al. [Feldman et al., 2009]), online nodes have types in our model. In contrast to the adversarial types studied in the known i.i.d. model, following the random graphs studied in Mastin and Jaillet [A. Mastin, 2013], in our model each type graph is generated randomly by including each offline node in the neighborhood of an online node with probability c/n independently. In our model, nodes of the same type appear consecutively in the input and the number of times each type node appears is distributed according to the Poisson distribution with parameter 1. We analyze the performance of the simple greedy algorithm under this input model. The performance is controlled by the parameter c and we are able to exactly characterize the competitive ratio for the regimes c = o(1) and c = omega(1). We also provide a precise bound on the expected size of the matching in the remaining regime of constant c. We compare our results to the previous work of Mastin and Jaillet who analyzed the simple greedy algorithm in the G_{n,n,p} model where each online node type occurs exactly once. We essentially show that the approach of Mastin and Jaillet can be extended to work for the Random Type Poisson Arrival Model, although several nontrivial technical challenges need to be overcome. Intuitively, one can view the Random Type Poisson Arrival Model as the G_{n,n,p} model with less randomness; that is, instead of each online node having a new type, each online node has a chance of repeating the previous type.

Subject Classification

ACM Subject Classification
  • Theory of computation → Graph algorithms analysis
  • Theory of computation → Online algorithms
Keywords
  • bipartite matching
  • stochastic input models
  • online algorithms
  • greedy algorithms

Metrics

  • Access Statistics
  • Total Accesses (updated on a weekly basis)
    0
    PDF Downloads
    0
    Metadata Views

Related Versions

References

  1. P. Jaillet A. Mastin. Greedy online bipartite matching on random graphs, 2013. URL: https://arxiv.org/abs/1307.2536v1.
  2. M. Zadimoghaddam B. Haeupler, V.S. Mirrokni. Online stochastic weighted matching: Improved approximation algorithms, WINE 2011. Google Scholar
  3. Bert Besser and Matthias Poloczek. Greedy matching: Guarantees and limitations. Algorithmica, 77(1):201-234, 2017. Google Scholar
  4. Bela Bollobás and Graham Brightwell. The width of random graph orders. The Mathematical Scientist, 20, 01 1995. Google Scholar
  5. Allan Borodin, Christodoulos Karavasilis, and Denis Pankratov. An experimental study of algorithms for online bipartite matching, Unpublished work in progress, 2018. Google Scholar
  6. Jon Feldman, Aranyak Mehta, Vahab Mirrokni, and S. Muthukrishnan. Online stochastic matching: Beating 1-1/e. In Proc. of FOCS, pages 117-126, 2009. Google Scholar
  7. Gagan Goel and Aranyak Mehta. Online budgeted matching in random input models with applications to adwords. In Proc. of SODA, pages 982-991, 2008. Google Scholar
  8. Carl W. Helstrom. Statistical Theory of Signal Detection (Second Edition, Revised and Enlarged). International Series of Monographs in Electronics and Instrumentation. Pergamon, second edition, revised and enlarged edition, 1968. Google Scholar
  9. Patrick Jaillet and Xin Lu. Online stochastic matching: New algorithms with better bounds. Mathematics of Operations Research, 39(3):624-646, 2014. Google Scholar
  10. R. M. Karp, U. V. Vazirani, and V. V. Vazirani. An optimal algorithm for on-line bipartite matching. In Proc. of STOC, pages 352-358, 1990. Google Scholar
  11. Jon M. Kleinberg. Bursty and hierarchical structure in streams. Data Min. Knowl. Discov., 7(4):373-397, 2003. Google Scholar
  12. Thomas G. Kurtz. Solutions of ordinary differential equations as limits of pure jump markov processes. Journal of Applied Probability, 7(1):49-58, 1970. Google Scholar
  13. A. Mehta. Online matching and ad allocation, Theoretical Computer Science, 8(4):265–368, 2012. Google Scholar
  14. Gordon Simons and N. L. Johnson. On the convergence of binomial to poisson distributions. Ann. Math. Statist., 42(5):1735-1736, 10 1971. URL: http://dx.doi.org/10.1214/aoms/1177693172.
  15. Kannikar Siriwong, Lester Lipsky, and Reda A. Ammar. Study of bursty internet traffic. In Sixth IEEE International Symposium on Network Computing and Applications (NCA 2007), 12 - 14 July 2007, Cambridge, MA, USA, pages 53-60, 2007. Google Scholar
  16. Stats Stackexchange. What is the expectation of the absolute value of the skellam distribution? https://stats.stackexchange.com/questions/279220/what-is-the-expectation-of-the-absolute-value-of-the-skellam-distribution. Accessed: 2018-04-11.
  17. A. Saberi V. H. Manshadi, S. Oveis Gharan. Online stochastic matching: Online actions based on offline statistics, Mathematics of Operations Research, 37(4):559-573, 2012. Google Scholar
  18. Nicholas C. Wormald. Differential equations for random processes and random graphs. Ann. Appl. Probab., 5(4):1217-1235, 11 1995. Google Scholar
  19. Nicholas C. Wormald. The differential equation method for random graph processes and greedy algorithms. In Lectures on approximation and randomized algorithms, pages 73-155, 1999. Google Scholar
Questions / Remarks / Feedback
X

Feedback for Dagstuhl Publishing


Thanks for your feedback!

Feedback submitted

Could not send message

Please try again later or send an E-mail
© 2023-2024 Schloss Dagstuhl – LZI GmbH Imprint Privacy Contact