Enhancing Capacity and Network Performance of Client-Server Architectures  Using Mobile IPv6 Host-Based Network Protocol

Enhancing Capacity and Network Performance of Client-Server Architectures Using Mobile IPv6 Host-Based Network Protocol

ruphin_kusinza_byamungu

Contact

Ruphin Kusinza Byamungu

Contact

α Hope Africa University

Enhancing Capacity and Network Performance of Client-Server Architectures Using Mobile IPv6 Host-Based Network Protocol

Article Fingerprint

ReserarchID

CSTNWSY7ISH

Enhancing Capacity and Network Performance of Client-Server Architectures Using Mobile IPv6 Host-Based Network Protocol Banner

AI TAKEAWAY

Connecting with the Eternal Ground

Abstract

A huge number of studies have been done supporting seamless mobility networks and mobile technologies over the years. The recent innovations in technology have unveiled another revolution from the static architectural approach to more dynamic and even mobile approaches for client-server networks. Due to the special equipments and infrastructure needed to support network mobility management, it is difficult to deploy such networks beyond the local network coverage without interruption of communications. Therefore, MIPv6 as developed by the Internet Engineering Task Force (IETF) and ancillary technologies were reviewed to provide clear insights on implementing MIPv6 in Client-Server architectures. However, MIPv6 technology presents weaknesses related to its critical handover latency which appears long for real-time applications such as Video Stream with potential loss of data packets during transmission.

References

36 Cites in Article

Reference Format

Sandra Cespedes,Xuemin Shen (2015). On Achieving Seamless IP Communications in Heterogeneous Vehicular Networks.
N Zhang,H Bao (2008). Study on Mobile IP Technology in Wireless Communication Systems.
Dong Ma,Maode Ma (2014). Network selection and resource allocation for multicast in HetNets.
W Goralski (2014). Learn About Differences in Addressing Between IPv4 and IPv6.
S Kim,D Kim (2006). Home Address allocation to mobile terminal over mobile IP environments.
Maryline Laurent-Maknavicius (2002). For a Secure Mobile IP and Mobile IPv6 Deployment.
Zesong Fei,Chengwen Xing,Na Li (2014). QoE-driven resource allocation for mobile IP services in wireless network.
S Opoku (2012). A Simultaneous-Movement Mobile Multiplayer Game Design Based on Adaptive Background Partitioning Technique.
C Perkins,D Johnson,J Arkko (2011). Mobility Support in IPv6.
S Glass,T Hiller,S Jacobs,C Perkins (2000). Mobile IP Authentication, Authorization, and Accounting Requirements.
P Lin,S Cheng,W Liao (2009). Modeling key caching for mobile IP authentication, authorization, and accounting (AAA) services.
Ge Yang,Zhenming Lei,Huan Wang,Yinan Dou,Yun Xie (2014). Analysis of the RADIUS Signalling Based on CDMA Mobile Network.
Charles Perkins (2002). Mobile IP and the IETF.
G Bai,C Williamson (2004). The effects of mobility on wireless media streaming performance.
Feng Xiaorong,Lin Jun,Jia Shizhun (2013). The research on mobile Ipv6 security features.
Vahid Heydari,Seong-Moo Yoo,Sun-Il Kim (2016). Secure VPN Using Mobile IPv6 Based Moving Target Defense.
D Rudolf (2009). Next Generation Internet : IPv4 Address Exhaustion, Mitigation Strategies and Implications for the U.S.
Olabenjo Babatunde,Omar Al-Debagy (2014). A Comparative Review Of Internet Protocol Version 4 (IPv4) and Internet Protocol Version 6 (IPv6).
Jonghwan Hyun,Jian Li,Hwankuk Kim,Jae-Hyoung Yoo,James Won-Ki Hong (2015). IPv4 and IPv6 performance comparison in IPv6 LTE network.
Teerapat Sanguankotchakorn,Preeda Jaiton (2008). Effect of Triangular Routing in Mixed IPv4/IPv6 Networks.
H Hamandi,D Al-Hemiary (2013). Simulation of Mobile IPv6 Using OMNeT ++ Simulator.
S Vaughan-Nichols (2003). Mobile IPv6 and the future of wireless internet access.
Basil Al-Kasasbeh,R Al-Qutaish,K Al-Sarayreh (2008). Semi-Direct Routing Approach for Mobile IP.
R Radhakrishnan,M Jamil,S Mehfuz (2008). Return Routability.
Muhammad Amin,Kamalrulnizam Bakar,Abdul Abdullah,Rashid Khokhar (2011). Reducing Handover Latency in Mobile IPv6-Based WLAN by Parallel Signal Execution at Layer 2 and Layer 3.
Ditchaphong Phoomikiattisak,Saleem Bhatti (2015). Mobility as a first class function.
Atheer Al-Rubaye,Yevgeniy Yeryomin,Jochen Seitz (2016). Evaluation of MCDM-based handover decision algorithms in OMNeT++.
R Koodli (2009). Mobile IPv6 Fast Handovers.
S Sendra,M Garcia,C Turro,J Lloret Unknown Title.
Luxmiram Vijayandran,Prathapasinghe Dharmawansa,Torbjorn Ekman,Chinthananda Tellambura (2011). Aggregate interference and system performance in finite area cognitive radio networks.
Federico Tramarin,Stefano Vitturi,Michele Luvisotto (2017). A Dynamic Rate Selection Algorithm for IEEE 802.11 Industrial Wireless LAN.
R Koodli (2010). Mobile IPv6 Fast Handovers.
V Vassiliou,Z Zinonos (2010). An Analysis of the Handover Latency Components in Mobile IPv6.
J Lai,Y Sekercioglu,N Jordan,A Pitsillides (2006). Performance Evaluation of Mobile IPv6 Handover Extensions in an IEEE 802.
Monji Zaidi,Jamila Bhar,Ridha Ouni,Rached Tourki (2011). Reducing Wi-Fi handover delay using a new positioning process.
Salim Abukharis,Jafar A. Alzubi,Omar A. Alzubi,Saeed Alamri,Tim Tim O\'farrell (2014). Packet Error Rate Performance of IEEE802.11g under Bluetooth Interface.

Download References

Funding

No external funding was declared for this work.

Conflict of Interest

The authors declare no conflict of interest.

Ethical Approval

No ethics committee approval was required for this article type.

Data Availability

Not applicable for this article.

How to Cite This Article

ruphin_kusinza_byamungu. 2021. \u201cEnhancing Capacity and Network Performance of Client-Server Architectures Using Mobile IPv6 Host-Based Network Protocol\u201d. Global Journal of Computer Science and Technology - E: Network, Web & Security GJCST-E Volume 20 (GJCST Volume 20 Issue E4): .

More Citation Formats

Select Citation Style:

Download Citation

Download Article

GJCST Volume 20 Issue E4
Pg. 29- 41

Explore Journals Explore Volume Read This Issue

Journal Specifications

Crossref Journal DOI 10.17406/gjcst

Print ISSN 0975-4350

e-ISSN 0975-4172

Keywords

Not Found

Classification

GJCST-E Classification: C.2.2

Submission ReceivedDecember 6, 2019
Peer Review Double Blind
Handling Editor
Accepted January 5, 2020
Published January 15, 2020

Version of record

v1.2

Issue date

January 13, 2021

Language

Experiance in AR

Explore published articles in an immersive Augmented Reality environment. Our platform converts research papers into interactive 3D books, allowing readers to view and interact with content using AR and VR compatible devices.

View in VR

Read in 3D

Your published article is automatically converted into a realistic 3D book. Flip through pages and read research papers in a more engaging and interactive format.

View in 3D

Article Matrices

Total Views: 4267

Total Downloads: 1048

2026 Trends

Published Article

Our website is actively being updated, and changes may occur frequently. Please clear your browser cache if needed. For feedback or error reporting, please email [email protected]