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Research on Behavior of Two New Random Entity Mobility Models in 3-D Space

  • Research Article-Computer Engineering and Computer Science
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Abstract

Mobile data collectors that can be used without a central control mechanism currently have common use in many fields. Because they do not need a central unit, each node in a network can move independently. The field literature offers various group- or entity-based models to define the functioning of mobile data collectors. In this study, a random entity mobility model (REMM) research was performed. The study was based on the models random walk (RW) and random waypoint (RWP), used in several former studies mentioned in the literature. Furthermore, the models random point (RP) and random journey (RJ) proposed by Bilgin [1] for two-dimensional (2D) space were transferred to three-dimensional (3D–cubic) to be used in the study. Study findings obtained by defining a various number of fixed nodes in areas of various sizes were analyzed using 4 different metrics. It was observed that 4 different metric values decreased for 4 REMMs when the cubic area was enlarged by increasing the edge lengths (150–200–250 pixel) of the cubic. When the cubic’s edge length is 150-200-250 pixel, respectively, connected node ratio (CNR) metric value is 98.04%–95.8%–91.34% for RP and 96.83%-83.23%-70% for RJ. Provided that the cubic area remains constant, the increases in the number of nodes generally tend to increase, although there are slight fluctuations on the results. When the cubic edge is 200 and the node numbers are 4–6–8–10, the message delay is 13.345–16.566–27.386–40.050 seconds for RW and 6.579–9.124–11.431–13.456 seconds for RWP. In the comparisons made by taking the average of the values obtained according to the size of the cubic area and the number of nodes, the RP model reached the highest values for all metrics. For example, the visited node ratio (VNR) metric average for the cubic edge 200 pixels is 98.76% for RP and 94.68%–87.38%–94.78% for RW–RWP–RJ. The VNR metric for the cubic edge 250 is 96.55%–93.7%–87.45%–51.27% for the RP–RW–RWP–RJ. Similarly, the average values obtained for other metrics prove this situation. In addition, when the results of the study are examined, it has been measured that the RP model can deliver the message to the base with less delay than other models. The average delay for the cubic edge 150 is 2.933–27.667–23.236–5.698 second for the RP–RW–RWP–RJ and 2.846–24.337–10.148-4.293 second when the edge is 200. When the average results obtained were examined, the success ranking in the delay metric was RP–RJ–RWP and RW, while the other metrics were formed as RP–RJ–RW–RWP. Considering all the obtained results, it was seen that the proposed two models achieved better results than the existing models in 3D after 2D.

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References

  1. Bilgin, M.: Novel random models of entity mobility models and performance analysis of random entity mobility models. Turkish J. Electr. Eng. Comput. Sci. 28, 708–726 (2020)

    Article  Google Scholar 

  2. Zordan, D.; Martinez, B.; Vilajosana, I.; Rossi, M.: On the Performance of Lossy Compression Schemes for Energy Constrained Sensor Networking. ACM Trans. Sensor Netw. 11(1), 1–34 (2014)

    Article  Google Scholar 

  3. Lin, Y.; Shen, H.: VShare: A wireless social network aided vehicle sharing system using hierarchical cloud architecture. IEEE First International Conference on Internet-of-Things Design and Implementation 37–48, (2016)

  4. Ibrar, M.; Ahmad, M.; Umar, M.; Habib, M.; Iqbal, M.: Stability analysis of DHT based multi-path routing protocol under group-based mobility models and entity-based mobility models in mobile ad-hoc networks. IEEE Information Technology, Networking. Electronic and Automation Control 777–783, (2016)

  5. Zheng, H.; Li, J.; Feng, X.; Guo, W.; Chen, Z.; Xiong, N.: Spatial-temporal data collection with compressive sensing in mobile sensor networks. Sensors 17(11), 2575 (2017)

    Article  Google Scholar 

  6. Nisar, M.A.; Mehmood, A.; Nadeem, A.: A Review and performance analysis of mobility models for MANETs: A case study. International Conference on Information and Communication Technologies 1–6, (2013)

  7. Camp, T.; Boleng, J.; Davies, V.: A survey of mobility models for ad hoc network research. Wireless Commun. Mobile Comput. 2(5), 483–502 (2002)

    Article  Google Scholar 

  8. Bai F., Helmy A.: A survey of mobility models in wireless adhoc networks, CiteSeerX -Scientific Literature Digital Library and Search Engine, (2008).

  9. Atsan, E.; Özkasap, Ö.: A classification and performance comparison of mobility models for ad hoc networks”. International Conference on Ad-Hoc Networks and Wireless 444–457, (2006)

  10. Manjula, S.H.; Abhilash, C.N.; Shaila, K.; Venugopal, K.R.; Patnaik, L.M.: Performance of AODV routing protocol using group and entity mobility models in wireless sensor networks. International MultiConference of Engineers and Computer Scientists 1212–1217, (2008)

  11. Biomo, J.D.; Kunz, T.; St-Hilaire, M.; Zhou, Y.: Unmanned aerial ad hoc networks: simulation-based evaluation of entity mobility models’ impact on routing performance. Aerospace 2(3), 392–422 (2015)

    Article  Google Scholar 

  12. Bilgin, M.; Şentürk, İF.: Network connectivity and data quality in crowd assisted networks. Crowd Assisted Networking and Computing 137–159, (2018)

  13. Nawaz, H.; Ali, H.M.A.: Study of mobility models for UAV communication networks. 3C Tecnologia 8(29), 276–297 (2019)

    Article  Google Scholar 

  14. Guillen-Perez, A.; Cano, M.D.: Flying ad hoc networks: A new domain for network communications. Sensors 18(10), 3571 (2018)

    Article  Google Scholar 

  15. Petit, J.; Lambiotte, R.; Carletti, T.: Classes of random walks on temporal networks. Appl. Netw. Sci. 4(1), 72 (2019)

    Article  Google Scholar 

  16. Hussaini, M.; Naeem, M.A.; Kim, B.S.; Maijama’a, I.S.: Efficient Producer Mobility Management Model in Information-Centric Networking. IEEE Access 7, 42032–42051 (2019)

    Article  Google Scholar 

  17. Yoshimura, Y.; Sinatra, R.; Krebs, A.; Ratti, C.: Analysis of visitors’ mobility patterns through random walk in the Louvre museum. Journal of Ambient Intelligence and Humanized Computing 1–16, (2019)

  18. Samouylov, K.E.E.; Gaidamaka, Y.V.; Shorgin, S.Y.: Modeling the movement of devices in a wireless network by random walk models. Informatics Appl. 12(4), 2–8 (2018)

    Google Scholar 

  19. Gupta, A.K.; Sadawarti, H.; Verma, A.K.: Performance analysis of MANET routing protocols in different mobility models”. Int. J. Inf. Technol. Comput. Sci. 5(6), 73–82 (2013)

    Google Scholar 

  20. Baloch, S.H.: Analysis of User Mobility Models Based on Outdoor Measurement Data and Literature Surveys, Master’s Thesis, (2014)

  21. Johnson, D.B.; Maltz, D.A.: Dynamic source routing in ad hoc wireless networks. In: Imielinski, T., Korth, H.F. (eds.) Mobile Computing, pp. 153–181. Springer, Berlin (1996)

    Chapter  Google Scholar 

  22. Camp, T.; Boleng, J.; Davies, V.: A survey of mobility models for ad hoc network research. Wireless Commun. Mobile Comput. 2(5), 483–502 (2002)

    Article  Google Scholar 

  23. Broch, J.; Maltz, D.A.; Johnson, D.B.; Hu, Y.C.; Jetcheva, J.: A performance comparison of multi-hop wireless ad hoc network routing protocols. IEEE international conference on Mobile computing and networking 85–97, (1998)

  24. Chiang, C.C.; Gerla, M.: On-demand multicast in mobile wireless networks. International Conference on Network Protocols 262–270, (1998)

  25. Einstein, A. Investigations on the Theory of the Brownian Movement. Courier Corporation, Editors: Fürth R.,Cowper A.D., Dover Publications, 1926 (1956).

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Authors and Affiliations

  1. Bursa Uludağ University, Bursa, Turkey

    Metin Bilgin

  2. Çanakkale Onsekiz Mart University, Çanakkale, Turkey

    Murat Eser

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  1. Metin Bilgin
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  2. Murat Eser
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Correspondence to Metin Bilgin.

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Bilgin, M., Eser, M. Research on Behavior of Two New Random Entity Mobility Models in 3-D Space. Arab J Sci Eng 47, 1159–1171 (2022). https://doi.org/10.1007/s13369-021-05785-3

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  • DOI: https://doi.org/10.1007/s13369-021-05785-3

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