11-09-2014, 12:07 PM
[color=#E0FF]OPTIMAL MULTISERVER CONFIGURATION FOR PROFIT MAXIMIZATION IN CLOUD COMPUTING[/color]
OPTIMAL MULTISERVER.doc (Size: 51 KB / Downloads: 10)
ABSTRACT
As cloud computing becomes more and more popular, understanding the economics of cloud computing becomes critically important. To maximize the profit, a service provider should understand both service charges and business costs, and how they are determined by the characteristics of the applications and the configuration of a multiserver system. The problem of optimal multiserver Configuration for profit maximization in a cloud computing environment is studied. Our pricing model takes such factors into considerations as the amount of a service, the workload of an application environment, the configuration of a multiserver system, the service-level agreement, the satisfaction of a consumer, the quality of a service, the penalty of a low-quality service, the cost of renting, the cost of energy consumption, and a service provider’s margin and profit. Our approach is to treat a multiserver system as an M/M/m queuing model, such that our optimization problem can be formulated and solved analytically. Two server speed and power consumption models are considered, namely, the idle-speed model and the constant-speed model. The probability density function of the waiting time of a newly arrived service request is derived. The expected service charge to a service request is calculated. The expected net business gain in one unit of time is obtained. Numerical calculations of the optimal server size and the optimal server speed are demonstrated.
[b] Scope:[/b]
Two server speed and power consumption models are considered, namely, the idle-speed model and the constant-speed model. The probability density function of the waiting time of a newly arrived service request is derived. The expected service charge to a service request is calculated. To the best of our knowledge, there has been no similar investigation in the literature, although the method of optimal multicore server processor configuration has been employed for other purposes, such as managing the power and performance tradeoff.
Existing System
To increase the revenue of business, a service provider can construct and configure a multiserver system with many servers of high speed. Since the actual service time (i.e., the task response time) contains task waiting time and task execution time. More servers reduce the waiting time and faster servers reduce both waiting time and execution time.
Problems on existing system:
1. In single Sever System if doing one job another process waiting for another completion of server service, So it take time to late.
2. Due to increase the Service cost of cloud.
3. Proposed System
we study the problem of optimal multiserver configuration for profit maximization in a cloud computing environment. Our approach is to treat a multiserver system as an M/M/m queuing model, such that our optimization problem can be formulated and solved analytically. We consider two server speed and power consumption models, namely, the idle-speed model and the constant-speed model.
ADVANTAGE:
We calculate the expected service charge to a service request. Based on these results, we get the expected net business gain in one unit of time, and obtain the optimal server size and the optimal server speed numerically
To the best of our knowledge, there has been no similar investigation in the literature, although the method of optimal multicore server processor configuration has been employed for other purposes, such as managing the power and performance tradeoff.
Mechanisms:
Multiple sporadic servers as a mechanism for rescheduling aperiodic tasks are applicable to today's computer environments. A developed simulation tool enables evaluation of its performance for various task sets and server parameters. By increasing the number of servers, aperiodic task response time is reduced; system utilization and the number of reschedulings are increased whereas periodic task execution is disrupted insignificantly. Proper selection of server parameters improves task response time, and decreases the number of unnecessary reschedulings. Simulation results prove model correctness and simulation accuracy. The simulator is applicable to developing rescheduling algorithms and their implementation into real environments.
IMPLEMENTATION
Implementation is the stage of the project when the theoretical design is turned out into a working system. Thus it can be considered to be the most critical stage in achieving a successful new system and in giving the user, confidence that the new system will work and be effective.
The implementation stage involves careful planning, investigation of the existing system and it’s constraints on implementation, designing of methods to achieve changeover and evaluation of changeover methods.
Main Modules:-
1. User Module
In this module, Users are having authentication and security to access the detail which is presented in the ontology system. Before accessing or searching the details user should have the account in that otherwise they should register first.
2. Multi-Server Mode
A cloud computing service provider serves users’ service requests by using a multiserver system, which is constructed and maintained by an infrastructure vendor and rented by the service provider.
The architecture detail of the multiserver system can be quite flexible.
3. Optimal Size and Speed:
Server size optimization has clear physical interpretation. When m is small such that _ is close to 1, the waiting times of service requests are excessively long, and the service charges and the net business gain are low.
CONCLUSION
we have proposed a pricing model for cloud computing which takes many factors into considerations, such as the requirement r of a service, the workload _ of an application environment, the configuration (m and s) of a multiserver system, the service level agreement c, the satisfaction (r and s0) of a consumer, the quality (W and T) of a service, the penalty d of a low-quality service, the cost (_ and m) of Renting, the cost
(_, , P_, and P) of energy consumption, and a service provider’s margin and profit a. By using an M/M/ m queuing model, we formulated and solved the problem of optimal multiserver configuration for profit maximization in a cloud computing environment. Our discussion can be easily extended to other service charge functions. Our methodology can be applied to other pricing models.