Implementasi Highly Available Website Dengan Distributed Replicated Block Device
Mulyanto Mulyanto(1), Ahmad Ashari(2*)
(1) Jurusan Informatika, Fakultas Ilmu Komputer, UMRI, Riau
(2) Universitas Gadjah Mada
(*) Corresponding Author
Abstract
As an important IT infrastructure, website is a system which requires high reliability and availability levels. Website meets the criteria as a highly available system because website must provide services to clients in real time, handle a large amount of data, and not lose data during transaction. A highly available system must meet the condition of being able to run continuously as well as guaranteeing consistency on data requests.
This study designed a website with high availability. The approach was building network cluster with failover and replicated block device functions. Failover was built to provide service availability, while replicated block device provides data consistency during failure of service. With failover cluster and replicated block device approaches, a cluster which is able to handle service failures of web server and database server on the website.
The result of this study was the services of the website could run well if there was any failure in node members of the cluster. The system was able to provide 99,999 (five nines) availability on database server services and 99,98 (three nines) on web server services.
Keywords
Full Text:
PDFReferences
[1] Atmaja, A. P., 2013, Tinjauan Implementasi Fragmentasi Elastis pada Database Non-Relational untuk Website Forum Diskusi, Tesis, Magister Ilmu Komputer FMIPA Universitas Gadjah Mada, Yogyakarta.
[2] Paudyal, U., 2011, Scalable web application using node.JS and CaouchDB, Institutionen för informationsteknologi, Department of Information technology, Uppsala: Sweden.
[3] Lin, Z., 2009, Research and Implement of High Availability for Web Server Cluster System, Proceedings of 2009 Conference on Communication Faculty, Scientific Research, Beijing.
[4] Ellenberg, L., 2009, DRBD 9 & Device Mapper, Linux Block Level Storage Replication, LINBIT, Vienna, Austria.
[5] Setyorini, T. A., 2010, Rancang Bangun Sistem Informasi Akademik yang Fault Tolerance, Tesis, Magister Ilmu Komputer FMIPA Universitas Gadjah Mada, Yogyakarta.
[6] Oei, S., 2011, Rancang Bangun Fault Tolerance pada Sistem Database Pada Sistem Database Untuk Aplikasi Point Of Sale, Tesis, Magister Ilmu Komputer FMIPA Universitas Gadjah Mada, Yogyakarta.
[7] Anggraini, L. H., 2012, Rancang Bangun Highly Available dan Reliable Server Database dengan Automatic Failover, Tesis, Magister Ilmu Komputer FMIPA Universitas Gadjah Mada, Yogyakarta.
[8] Afif, M. F., Suryono, T., 2013. Implementasi Disaster Recovery Plan Dengan Sistem Fail over Menggunakan DRBD dan Heartbeat Pada Data Center FKIP UNS. Indonesian Jurnal on Networking and Security (IJNS) Volume 2 No 2 – April 2013 - ISSN: 2302-5700 (p. 64-69).
[9] Schmidt, K., 2006, High Availability and Disaster Recovery Concepts, Design, Implementation, Springer-Verlag, Berlin.
[10] Tanenbaum, A. S. dan Steen, M. V., 2002, Distributed System Principles and Paradigms, Prentice Hall.
[11] Marcus, E., Stern, H., 2003, Blueprints for high availability 2nd Edition, John Wiley & Sons: Indianapolis.
[12] Depuydt, J., 2014, Building a high-available failover cluster with Pacemaker, Corosync & PCS, http://jensd.be/?p=156, Diakses 24 April 2015.
[13] Lowe, D., 2005, Networking for Dummies, Seventh Edition, Wiley Publishing: New York.
[14] Dake, C. S., Caulfield, C., Beekhof, A., 2008, the Corosync Cluster Engine, Linux Symposium, Vol. 1, Ottawa, Ontario, Canada.
DOI: https://doi.org/10.22146/ijccs.15528
Article Metrics
Abstract views : 3088 | views : 3831Refbacks
- There are currently no refbacks.
Copyright (c) 2016 IJCCS - Indonesian Journal of Computing and Cybernetics Systems
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
View My Stats1