Open Access   Article Go Back

An Algorithm to Find the Directed Minimum Spanning Trees

A. Navis Vigilia1 , J. Suresh Suseela2

Section:Research Paper, Product Type: Journal Paper
Volume-7 , Issue-9 , Page no. 233-239, Sep-2019

CrossRef-DOI:   https://doi.org/10.26438/ijcse/v7i9.233239

Online published on Sep 30, 2019

Copyright © A. Navis Vigilia, J. Suresh Suseela . This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

View this paper at   Google Scholar | DPI Digital Library

XML View
PDF Download

How to Cite this Paper

  • IEEE Citation
  • MLA Citation
  • APA Citation
  • BibTex Citation
  • RIS Citation

IEEE Style Citation: A. Navis Vigilia, J. Suresh Suseela, “An Algorithm to Find the Directed Minimum Spanning Trees,” International Journal of Computer Sciences and Engineering, Vol.7, Issue.9, pp.233-239, 2019.

MLA Style Citation: A. Navis Vigilia, J. Suresh Suseela "An Algorithm to Find the Directed Minimum Spanning Trees." International Journal of Computer Sciences and Engineering 7.9 (2019): 233-239.

APA Style Citation: A. Navis Vigilia, J. Suresh Suseela, (2019). An Algorithm to Find the Directed Minimum Spanning Trees. International Journal of Computer Sciences and Engineering, 7(9), 233-239.

BibTex Style Citation:
@article{Vigilia_2019,
author = {A. Navis Vigilia, J. Suresh Suseela},
title = {An Algorithm to Find the Directed Minimum Spanning Trees},
journal = {International Journal of Computer Sciences and Engineering},
issue_date = {9 2019},
volume = {7},
Issue = {9},
month = {9},
year = {2019},
issn = {2347-2693},
pages = {233-239},
url = {https://www.ijcseonline.org/full_paper_view.php?paper_id=4884},
doi = {https://doi.org/10.26438/ijcse/v7i9.233239}
publisher = {IJCSE, Indore, INDIA},
}

RIS Style Citation:
TY - JOUR
DO = {https://doi.org/10.26438/ijcse/v7i9.233239}
UR - https://www.ijcseonline.org/full_paper_view.php?paper_id=4884
TI - An Algorithm to Find the Directed Minimum Spanning Trees
T2 - International Journal of Computer Sciences and Engineering
AU - A. Navis Vigilia, J. Suresh Suseela
PY - 2019
DA - 2019/09/30
PB - IJCSE, Indore, INDIA
SP - 233-239
IS - 9
VL - 7
SN - 2347-2693
ER -

VIEWS PDF XML
295 194 downloads 128 downloads
  
  
           

Abstract

New technologies and the deployment of mobile and nomadic services are driving the emergence of complex communications networks that have highly dynamic behaviour. This naturally engenders new route-discovery problems under changing conditions over these networks. Unfortunately, the temporal variations in the network topology are hard to be effectively captured in a classical graph model. In this paper, we use and extend a recently proposed graph theoretic model, which helps capture the evolving characteristic of such networks, in order to compute multicast trees with minimum overall transmission time for a class of wireless mobile dynamic networks. We first show that computing different types of strongly connected components in this model in NP-Complete, and then propose an algorithm to build all rooted directly minimum spanning trees in already identified strongly connected components.

Key-Words / Index Term

Wireless networks, mobile networks, multicast, evolving graphs, LEO satellites, minimum spanning trees, strongly connected components, graph theoretic models, NP-complete

References

[1]. Y. J Chu amd T H. Liu. On the shortest arborescence of a directed graph. Science Sincia, 14:1396- 1400, 1965
[2]. T. Cormen, C. Leiserson and R. Rivest. Introduction to Algorithms. The MIT Press, 1990
[3]. C.Scheideler. Models and techniques for communication in dunamic networks. In In H. Alt and A. Ferreira, editors, Proceedings of the 19th International Symposium on Theoretical Aspecys of Computer Science, volume 2285, pages 27-19. Springer-Verlag, March 2002.
[4]. E. Ekici, I. F Akyildiz, and M. D. Bender. Datagram routing algorithm for LEO satellite networks. In IEEE infocom, pages 500-508,2000.
[5]. Ferreira, on models and algorithms for dmanic communication networks: The case for evolving graphs. In Proceedings of 4e rencontres francophnes sur les Aspects Algorithmiques des Telecommunications (ALGOTEL ’2002), Meze, France, May 2002.
[6]. Fereira, J. Galtier, and P. Penna. Topological design, routing and handover in satellite networks. In I. Stojmenovic, editor, Handbook of wireless Networks and Mobile Computing, pages 473-493, John Wiley and Sons, 2002.
[7]. P. A Humblet. A distributed algorithm for minimum weight directed spanning trees. IEEE transactions on communications, COM-31(6): 756-762, 1983.
[8]. R. E. Tarjan. Finding optimum branching. Networks, pages 25-35, 1977.
[9]. P.-J. Wan, G, Calinescue, X. Li, and O. Frieder. Minimum-energy broadcast routing in static ad hoc wireless networks. In Proc. IEEE infocom, pages 1162-1171, Anchorage Alaska, 2001.
[10]. M. Werner and G. Maral. Traffic flows and dynamic routing in leo intersatellite link networks. In In Proceedings 5th International Mobile Satellite Conference (IMSC ’97), Pasadena, California, USA, June 1997.
[11]. M. Werner and F. Wauquiez. Capacity dimensioning of ISL networks in broadband LEO satellite systems. In sixth International Mobile Satellite Conference : IMSC ’99, pages 334-341, Ottawa, Canada, June 1999.
[12]. J. Wieselthier, G. Nguyen, and A. Ephremides. On the construction of energy-efficient broadcast and multicast trees in wireless networks. In proc. IEEE infocom, pages585-594, Tel Aviv, 2000