Participating-Domain Segmentation Based Delay-Sensitive Distributed Server Selection Scheme

This paper proposes a participating-domain segmentation based server selection scheme in a delay-sensitive distributed communication approach to reducing the computational time for solving the server selection problem. The proposed scheme divides the users’ participation domain into a number of regions. The delay between a region and a server is a function of locations of the region and the server. The length between the region and the server is considered based on conservative approximation. The location of the region is determined regardless of the number of users and their participation location. The proposed scheme includes two phases. The first phase uses the server finding process and determines the number of users that are accommodated from each region by each server, instead of actual server selection, to reduce the computational complexity. The second phase uses the delay improvement process and determines the overall delay and the selected server for each user. We formulate an integer linear programming problem for the server selection in the proposed scheme and evaluate the performance in terms of computation time and delay. The numerical results indicate that the computational time using the proposed scheme is smaller than that of the conventional scheme, and the effectiveness of the proposed scheme enhances as the number of users increases.

[1]  Weisong Shi,et al.  The Promise of Edge Computing , 2016, Computer.

[2]  Gwendal Simon,et al.  A hybrid edge-cloud architecture for reducing on-demand gaming latency , 2014, Multimedia Systems.

[3]  Noriyuki Takahashi,et al.  Analysis of Process Assignment in Multi-tier mobile Cloud Computing and Application to Edge Accelerated Web Browsing , 2015, 2015 3rd IEEE International Conference on Mobile Cloud Computing, Services, and Engineering.

[4]  Takehiro Ito,et al.  Tight Approximability of the Server Allocation Problem for Real-Time Applications , 2017, ALGOCLOUD.

[5]  R.M. Fujimoto,et al.  Parallel and distributed simulation systems , 2001, Proceeding of the 2001 Winter Simulation Conference (Cat. No.01CH37304).

[6]  Teruo Higashino,et al.  Edge-centric Computing: Vision and Challenges , 2015, CCRV.

[7]  Eiji Oki,et al.  Participating-Domain Segmentation Based Server Selection Scheme in Delay-Sensitive Distributed Communication Approach , 2018, 2018 IEEE Conference on Network Function Virtualization and Software Defined Networks (NFV-SDN).

[8]  Matti Siekkinen,et al.  Towards pervasive and mobile gaming with distributed cloud infrastructure , 2014, 2014 13th Annual Workshop on Network and Systems Support for Games.

[9]  Eiji Oki,et al.  A Real-Time Delay-Sensitive Communication Approach Based on Distributed Processing , 2017, IEEE Access.

[10]  André Schiper,et al.  Lightweight causal and atomic group multicast , 1991, TOCS.

[11]  Richard M. Fujimoto,et al.  Research Challenges in Parallel and Distributed Simulation , 2016, ACM Trans. Model. Comput. Simul..

[12]  Filip De Turck,et al.  Network Function Virtualization: State-of-the-Art and Research Challenges , 2015, IEEE Communications Surveys & Tutorials.

[13]  Yoji Yamato Server Selection, Configuration and Reconfiguration Technology for IaaS Cloud with Multiple Server Types , 2017, Journal of Network and Systems Management.

[14]  Sudarshan K. Dhall,et al.  On the game server network selection with delay and delay variation constraints , 2011, 2011 Third International Conference on Communication Systems and Networks (COMSNETS 2011).

[15]  Roberto Baldoni,et al.  A classification of total order specifications and its application to fixed sequencer-based implementations , 2006, J. Parallel Distributed Comput..

[16]  Rob Sherwood,et al.  The controller placement problem , 2012, HotSDN@SIGCOMM.

[17]  Sudarshan K. Dhall,et al.  Server selection with delay constraints for online games , 2010, 2010 IEEE Globecom Workshops.

[18]  Eiji Oki,et al.  Distributed processing communication scheme for real-time applications considering admissible delay , 2016, 2016 IEEE International Workshop Technical Committee on Communications Quality and Reliability (CQR 2016).