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Enterprises providing services through Internet must use online services supplied by other enterprises to compose the final services required by their end clients. The paper is aimed at providing services to the organization using service categorization mechanism which ensures stable QOS guarantees. This mechanism considers classes of requests and categories of consumers. It groups the requests carried out by consumers in secure sessions. In order that consumer servers can provide end clients with the appropriate quality of service, they must be guaranteed a determined QoS from the provider server. Under overload, this mechanism favors premium customers over basic customers so that premium customers can be protected, which maximizes the throughput and minimizes the response time. The main objective of this paper is QOS Control mechanism carries out an effective differentiation of the service provided to the consumers. It also focuses the reserving the processing capacity of the cluster for the preferential consumers during the overload periods.

Service Differentiation, Provider Server, Consumer Server, QOS

L. Eggert and J. Heidemann, “Application-Level Differentiated Services for Web Servers,” World-Wide Web J., vol. 2, no. 3, pp. 133-142, Aug. 1999

J. Almeida, M. Dabu, A. Manikutty, and P. Cao, “Providing Differentiated Levels of Service in Web Content Hosting,” Proc. First Workshop Internet Server Performance (WISP ’98), June 1998.

T.F. Abdelzaher and K.G. Shin, “QoS Provisioning with qCon- tracts in Web and Multimedia Servers,” Proc. 20th Real-Time Systems Symp. (RTSS ’99), pp. 44-53, Dec. 1999.

P. Pradhan, R. Tewari, S. Sahu, C. Chandra, and P. Shenoy, “An Observation-Based Approach Toward Self-Managing Web Servers,” Proc. 10th Int’l Workshop Quality of Service (IWQoS ’02), May2002.

A. Sharma, H. Adankar, and S. Sengupta, “Managing QoS Through Prioritization in Web Services,” Proc. Fourth Web Information Systems Eng. Workshop (WISEW ’03), pp. 140- 148, Dec. 2003.

B. Schroeder and M. Harchol-Balter, “Web Servers Under Over- load: How Scheduling Can Help,” Technical Report CMU-CS-02-143, Computer Science Dept., Carnegie-Mellon Univ., 2002.

Y. McWherter, B. Schroeder, A. Ailamaki, and M. Harchol-Balter, “Priority Mechanisms for OLTP and Transactional Web Applica- tions,” Proc. Int’l Conf. Data Eng. (ICDE ’04), pp. 535- 546, 2004.

B. Schroeder, M. Harchol-Balter, A. Iyengar, and E.M. Nahum, “Achieving Class-Based QoS for Transactional Workloads,” Proc.22nd Int’l Conf. Data Eng. (ICDE ’06), p. 153, Apr. 2006.

A. Totok and V. Karamcheti, “Improving Performance of Internet Services through Reward-Driven Request Prioritization,” Proc.14th Int’l Workshop Quality of Service (IWQoS ’06), June 2006.

J. Wei, X. Zhou, and C.-Z. Xu, “Robust Processing Rate Allocation for Proportional Slowdown Differentiation on Internet Servers,” IEEE Trans. Computers, vol. 54, no. 8, pp. 964-977, Aug. 2005.

N. Bhatti and R. Friedrich, “Web Server Support for Tiered Services,” IEEE Network Magazine, vol. 13, no. 5, pp-64- 71, 1999.

P. Bhoj, S. Ramanathan, and S. Singhal, “Web2K: Bringing QoS to Web Servers,” technical report, Internet Systems and Applications Laboratory, HP Laboratories, May 2000.

K. Li and S. Jamin, “A Measurement-Based Admission-Controlled Web Server,” Proc. IEEE INFOCOM, Mar. 2000.

B. Urgaonkar and P. Shenoy, “Cataclysm: Policing Extreme Overload in Internet Applications,” Proc. 14th World Wide Web Conf., pp. 740-749, May 2005.

B. Urgaonkar, “Dynamic Resource Management in Internet Hosting Platforms,” PhD dissertation, Computer Science Dept., Univ. of Massachusetts, Amherst, Sept. 2005.