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Evaluation of Parameters Importance in Cloud Service Selection Using Rough Sets

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DOI: 10.4236/am.2016.76049    1,564 Downloads   2,057 Views   Citations

ABSTRACT

With the rapid development of the cloud computing technology, it has matured enough for a lot of individuals and organizations to move their work into the cloud. Correspondingly, a variety of cloud services are emerging. It is a key issue to assess the cloud services in order to help the cloud users select the most suitable cloud service and the cloud providers offer this service with the highest quality. The criteria parameters defining the cloud services are complex which lead to cloud service deviation. In this paper, we propose an assessment method of parameters importance in cloud services using rough set theory. The method can effectively compute the importance of cloud services parameters and sort them. On the one hand, the calculation can be used as the credible reference when users choose their appropriate cloud services. On the other hand, it can help cloud service providers to meet user requirements and enhance the user experience. The simulation results show the effectiveness of the method and its relevance in the cloud context.

Received 12 February 2016; accepted 27 March 2016; published 30 March 2016

1. Introduction

For several years, cloud computing has been influencing the IT landscape and becomes an important economic factor [1] due to its mode of operation that is the pay-as-you-go to provide service. Since cloud computing is a minimal barrier to entry and economic scaling, there are a lot of prospective clients to move their business on it. In this context, many small and large cloud service providers emerge every day. However, not all of them are the first-hand owners of a cloud infrastructure. This means that for those smaller cloud service providers, they are only partnered with a bigger provider which owns the infrastructure. Normally, this is not a big problem, even though they are all connected to a bigger infrastructure provider, when it goes down, all “agentmiddleman” go down with it. Since cloud service providers have their specific service model, therefore, it is difficult for users to compare the cloud services offered by the different providers. Consequently, the cloud users face a challenge to select an appropriate provider taking into account their specific requirements.

Some cloud users take into consideration only their subjective preference parameters of the assessment criteria, while ignoring the importance of objective assessment parameters obtained from other customers who have the same service requirements when they are selecting the cloud services. Most cloud users cannot find an appropriate cloud service matching their individual requirements when they are using a given cloud service for the first. In fact, as they are not sure that the performance and quality of the selected service are good, they choose on the basis of their subjective judgment to the adapted decision parameters. Furthermore, when cloud users try to give an overall assessment for a cloud service, it is also not objective that the parameter weights of cloud service are generated usually subjective experience or experts scoring. This affects the cloud users’ choice of a suitable cloud service.

For all the issues mentioned above, we can obtain the importance rating of attributes and rank them through the rough set theory; thereby we determine the objective weight of the assessment indexes of cloud services. Our proposal not only can guide cloud users, facing a lot of choices of cloud services, concerning assessment indexes they should focus more, but also helps cloud providers to improve the performance and quality of the cloud services with the emphasis to attract more cloud users to make themselves have a predominance in future competition of IT industry.

2. Related Works

With the development of cloud computing technology, the cloud service is becoming a mature concept concerning the delivery of software services, infrastructure services and platform services. Many techniques have been proposed by researchers from academia and industry for cloud services publication, interface definition and service discovery. Cloud service techniques (e.g., virtualization technique) have greatly accelerated the adoption and deployment of cloud services.

Different from research emphasis of the above works, our study focuses on the parameters importance evaluation to guide users in cloud services selection. To get a rational evaluation result for each cloud service parameter, we use the rough set theory to carry out our work. In [12] , the author proposed an approach for mining significant factors affecting the adoption of SaaS using the rough set theory. Although we are using the same theory in a similar context, our work makes a further study. The method we proposed not only can explore the significant factors but also can rank and weight these parameters in cloud services selection.

3. Evaluation Parameters of Cloud Service

With the rapid development of cloud computing, more and more cloud service providers join cloud market. Businesses and consumers have more choices because a large number of industry application solutions emerge. The global market scale for cloud services is increasing. Cloud computing providers carry on the business on a unified platform by building cloud resource pool for resource sharing, resource centralization, service network, billing and demand elasticity, to achieve cloud business structure on a scale. From a marketing perspective, the main types of cloud services are cloud hosting services, object storage services, cloud database services, cloud engine services, block storage services, cloud caching services, on-line application services, load balancing services and cloud distribution services. From another perspective, cloud services include IaaS, PaaS and SaaS. Moreover, cloud can be divided into public cloud, private cloud and hybrid cloud on deployment).

The core business is various from different cloud service providers. For example, Amazon’s business is more interested in the platform and software (PaaS and SaaS), which are public cloud services. However, IBM has a wider range of business, and its hardware and platforms are more advanced; IaaS, PaaS, SaaS and other aspects of the business are involved, it is favored in building private and hybrid clouds. Therefore, it is difficult for the user to define what cloud service providers are the best on the basis of a certain point. There are some configuration parameters for every type of cloud services to assess their performance. For example, the number of CPU, the size of memory, the space of storage, operate system and so on, these parameters determine the performance of cloud hosting services. When users are choosing one type cloud service, there are many alternative cloud service providers. When users make choices they need some parameters to evaluate cloud service providers’ comprehensive ability, such as the capacity for innovation, the service capability, product technologies, the solutions, brand influence. Usual evaluation parameters of cloud service and cloud services providers as follows.

Ÿ Cloud service availability: availability is the proportion of time a system in functioning condition. For cloud service availability, it can be defined as the capacity of an IT system to provide continuous service delivery. We give an example to understand what exactly it means. Let’s take a 99.9% SLA (service-level agreement), in practice, this means that in any given month (assuming a 30-day month), the service can only be unavailable for about 4 minutes and a few seconds, or only about 50 minutes per year. It includes connectivity, reliability, delay, data leakage and the tenant’s business does not meet expectations or entirely suspended caused by any accident on IaaS, PaaS and SaaS. As cloud services mature, cloud service availability becomes as important as price or other factors in choosing the right service provider.

Ÿ Cloud service scalability: scalability is a broad concept. It appears in a wide range of applications. For cloud service, simply speak, scalability is the ability of the whole system to sustain increasing workloads by making use of additional resources. It is about how to deal with the large-scale business and attract more users. It is not directly related to how well the actual resource demands are matched by the provisioned resources at any point in time, even if there is more than a single point of failure. However, scalability of cloud service composition needs to meet the requirement for expanding users and technology upgrade.

Ÿ Cloud service security: Cloud service concerns a number of security issues [14] ,such as software platform security and infrastructure security via the cloud. Cloud service providers must ensure their clients’ data and applications are protected, while users can through authentication enhance their application security. Cloud service providers often store many users’ data on the same server to save costs, conserve resources and maintain efficiency. As a result, there is a chance that user’s private data can be viewed by other users without taking effective measures. Moreover, the precautionary measures to prevent Internet from hacking and virus damage. Therefore, cloud service security is an important index when evaluating the quality of the service.

Ÿ Capacity of innovation: innovation is described in terms of changes in what a company offers the product or service upgrade and the ways it creates and delivers those offerings (process improvement) [15] . Innovation is the soul of enterprise progress, the core of economic competition. An enterprise’s ability to innovate is a key to its success. When most competitors within an industry have acquired the same level of competence in areas of management, such as marketing operations, human resources and strategy, they need to look for some innovations, such as incentive, resource investment and enterprise’s self-fulfillment as a key factor for significant competitive advantages

Ÿ Total Cost of Ownership: Total Cost of Ownership (TCO) is an analysis technology to uncover all the lifetime costs that follow from owning certain kinds of assets. TCO provides a cost basis for determining the total economic value of an investment when incorporated in any financial benefit analysis [16] . TCO analysis attempts to uncover both the obvious costs and the “hidden” costs of ownership. Obvious costs in TCO are the costs involved during planning and vendor selection, such as purchase cost and the actual price paid. "Hidden" costs include acquisition costs, upgrade costs, security costs and so on. TCO is a scientific, rational economic evaluation index for firms.

Ÿ Service capability: Service capability is the degree of capability in a service system to provide services and is commonly defined as the maximum output rate of the system. Compared with the manufacturing industry, service capability of IT enterprises stresses the technology and skills to meet the needs of customers with high quality serving products [17] [18] . Enhancing of service capability can improve competitive advantages.

Ÿ Solution: For some problems (such as deficiency, demands, shortage) that already occurred or can be predicted in an enterprise, solution is a specific plan or proposal that can be effectively implemented. An excellent solution offers a series of conclusion: Why it happens? Whether it occurs again or not? Does it lead to other problems? How to avoid related problems? What experiences are accumulated from the solution? [19] As well as in some fields, solution should meet customers’ demands to achieve the expected effects.

Ÿ Brand influence: Brand influence refers to the ability of opening up market and gaining the benefits with the brand [20] [21] . It has been an important element for customers to choose their cloud service providers.

4. Rough Set Theory

Rough set theory proposed by Pawlark in [22] is a mathematical approach to uncertain knowledge. Rough set theory has been applied in many interesting areas. The rough set approach is of fundamental importance to artificial intelligence and cognitive sciences, especially in the fields of machine learning, knowledge acquisition, knowledge discovery, decision analysis, expert systems, inductive reasoning and pattern recognition [23] . The main advantage of rough set theory in the process of knowledge analysis is based on dataset rather than subjective judgment.

Definition 1 [22] [24] [25] . Let be an information system, where is the finite set of objects; is the set of attributes, C is a conditional attributes set, D is the decision attribute set; where is the set of values of attributes. f is an information function and denotes the map of, which means a value to each attribute for each object.

Definition 2 [22] [24] [25] . Given an information system,. The expression, called a positive region of the partition U/D with respect to condition attributes C, is the set of all elements of U that can be uniquely classified to blocks of the partition U/D, by means of C. U/D indicates elementary concepts of information system T about decision attribute set D. For, we have:

a) If, then is an unnecessary attribute of C;

b) If, then is a necessary attribute of C.

Definition 3 [22] [24] [25] . Given an information system,. Attribute importance of the decision information system can be tested by the classification ability for T when removing an attribute from condition attribute set C, the significance of the attribute is defined by [22] as in:

(1)

Card presents the set cardinality of the attributes. represents the dependence of decision attribute D relative to condition attribute, and which reflects the classification discrimination ability of the attribute. The larger value of, the more stronger of dependency relationships between condition attribute and decision attribute D, and the more discriminative the attribute is.

5. The Cloud Service Selection Method with Preference Information

Cloud users usually give the subjective weight to different parameters of the cloud service based on personal preference when they are choosing the cloud service, thus resulting into non practical choices. Therefore, in this section we introduce an approach to rank the importance of the cloud service indexes and provide the objective weight about different parameters based on the rough set theory.

5.1. The Objective Ranking of Attributes Approach Based on Rough Set Theory

Rough set theory analysis is based on upper and lower approximations space. The lower approximation of the set can describe the precise knowledge in an information system, which is called positive region and is defined by Definition 2. If the lower approximation will not be changed when an attribute is deleted, then the attribute is unnecessary and can be reduced. Otherwise, the attribute is called core attribute, which is necessary. In other words, the Definition 2 can distinguish the core attributes and unnecessary attributes while ignoring the effect of the relatively necessary attributes. For all relatively necessary attributes, we can rank them in an information system according to the significance values of different attributes. The significance of an attribute defined by Definition 3 can reflect the variety of the lower approximation space when the attribute is deleted.

Since cloud service is characterized by various parameters, such as availability or scalability, elasticity and so on, it is difficult to define selection criteria valid for different customer needs. For this problem, we give a cloud service selection method using rough set theory to help user make decision.

We construct an information system based on a large preference datasets collected from users of certain cloud service providers (google, Alibaba et al). Table 2 is an assessment and requirement system of users about the cloud services. U represents the cloud services set,; Condition attributes set represents the assessment parameters of cloud services, C = {availability, scalability, reliability, credit, …, loads}, that is; decision attribute set is satisfied with the cloud service or not, D = {Yes, No}, that is, {1, 0}, where, * represents incomplete information.

Figure 1. Getting the preference information.

Table 1. The preference levels of users.

To obtain the parameters importance of cloud service, the ranking of attributes algorithm as follows:

5.2. Application of the Objective Ranking of Attributes Approach in Cloud Service Selection

Choosing the cloud services is a multiple attributes decision making problem, and the key is to determine the weight of parameters. There are several ways to determine the weight of indicators, on general, which fall into two categories: subjective and objective assignment methods. The subjective assignment method is assigning weight based on subjective information of decision-making. It is arbitrary with poor accuracy and reliability of decision-making. In the objective assignment method, each parameter is evaluated with the actual data. In cloud service selection system, the importance of attributes is different. The objective weight of attributes can be defined as in (2):

(2)

The comprehensive weight with regard to parameters can be defined as in (3):

(3)

where, which is called weight coefficient reflects cloud user preference for subjective and objective weights of parameter when they make decisions in cloud services selection. and respectively represents the weight of parameters of cloud services with objective dataset and subjective dataset. Smaller value of indicates that users value more their subjective preference. Conversely, higher value of users emphasizes the objective importance of parameters. Specially, if, users judging the parameters’ importance of cloud services totally depend on their subjective awareness; if, users completely rely on the objective weight.

Figure 2. Application model of the objective ranking of attributes.

5.3. Application of Attributes Ranking Approach in Cloud Service Selection

There are corresponding indexes designed to evaluate a system or a service. When cloud service providers launch a service product to consumers, they should provide quality of services and they hope to get the feedback from consumers early to improve their products, at the same time, the evaluation indexes of the services to be design accordingly. For cloud service users, when they choose a cloud service, they will consider some factors to obtain the suitable service, such as cloud service availability, cloud service elasticity, brand of service etc. As we know, in economical market, the cost control and the pursuit of efficiency are the primary goals of each company management. The reason cloud users choose moving their business to cloud computing center is because this is a good way to save capital and improve efficiency compare to their traditional development model. However, in practice, cloud users should balance the weight of factors used to evaluate cloud service.

Here we demonstrate an instance to use rough set theory to rank the factors of cloud service providers because the overall strength of cloud service provider is important for cloud users to choose the suitable cloud service. The real data in Table 3 is the list of cloud service providers according to their all-round capacity in 2014. The cloud service providers operate in China. The data is published in the journal of China Internet Weekly [26] . In Table 3, the factors CI (capacity for innovation), SC (service capability), PT (product technologies), S (solution), TCO (total cost of ownership) and BI (Brand influence) are the evaluation factors of cloud service providers. The factor CS (comprehensive score) is the assessment result of the cloud service providers.

In rough set theory, every cloud service provider is represented as a research object, and the factors as its attributes. Among them, the factor CS is decision attribute, while others are condition attributes. Simply, columns of Table 3 are attributes and rows are objects, whereas entries of the table are attribute values. Thus, each row of the table can be seen as information about specific cloud service provider. Our research purpose is to rank the weight of the factors to assess the comprehensive strength of cloud service providers.

In order to decide the weight of factors of cloud service providers to assess their comprehensive strength, we can get the attributes rank and weight values of Table 3 by the ranking of attributes algorithm we proposed which are shown in Table 4. It shows that the factor S is very important than other factors when the given parameters are used for evaluating cloud service providers. The weights of the factor TCO and BI are the smallest ones. They are not the key factors. According to the result of ranking factors, we able to reduce flexibly the evaluation factors.

5.4. An Example of Application of the Objective Ranking of Attributes Approach in Cloud Service Selection

We give an example to explain how to apply our model with personal preference. Table 5 and Table 6 are two information systems respectively based on the user preference dataset and the third-party objective dataset. To distinguish cloud service elements of subjective dataset and objective dataset, we use sj(j = 1, 2, ∙∙∙, 9) and ek(k = 1, 2, …, 20) to represent respectively the cloud service elements in Table 5 and Table 6. Attribute i(i = 1, 2, 3, 4) represents various parameters of cloud services. The value of attribute d is used to show the different decision results per cloud service. They are shown as follows.

Table 3. The scores of cloud service providers.

Table 4. The ranking and weight of attributes.

Table 5. Users’ preference information dataset.

Table 6. Third party objective dataset.

We can get the attributes rank, significance and weight values of Table 5 and Table 6 by Definition 2, 3 and Equation (2), or we get the result integrating Algorithm 1 and Equation (2). The results are shown in Table 7. According to Equation (3), we can obtain the attributes ranking of cloud services with different values of weight coefficient β shown in Table 8.

6. Experiments Result and Analysis

The experiment has two goals. The first one aims for sorting the parameters of cloud services according to their significance to guide the new cloud service users to make decision. The second one aims to prove the method is effective in the application of the cloud services selection with preference information. Due to lack of the related standard test platform of users’ preference and the standard test datasets, here we adopt data sets (download from the UCI [27] ) as the training samples to carry out. Besides that, the original datasets are pre-processed to be easily used for calculating and program designing.

Table 9 shows the basic information of the data sets. Programming code is by Java language. It is executed sequentially on a processor Intel Core2 Duo CPUs x64. The main function of the algorithm is to give the importance order of the attributes. We can get the comprehensive weights of attributes according to the result of ranking and significance of attributes. We can get the ranking attributes by setting the different values of weight coefficient β. Thus we compare to the services matching rate successfully. The experiment regards the objective datasets as the benchmark for analysis to draw graphic. Services matching is used to describe the intention of the selection of cloud users for cloud services providers. We can get the result shown in Figure 3.

Table 7. The ranking, significance and weight of attributes.

Table 8. Ranking for attributes selection.

Table 9. Basic information of test datasets.

Figure 3. Cloud services match-making with various value of β.

It can be seen from Figure 3 that with weight coefficient β greater, users’ subjective preference becomes important, and the service match-making rate decreases; rather, combining the subjective data and objective data, the cloud service match-making rate increases.

The users with the different subjective preference of the attribute weight use the random data to get the subjective service matching rate. As mentioned above, we use the rough set methods to get the objective weight of the attribute, integrating the objective and subjective weight to get the comprehensive matching rate of the service. Here, we set weight coefficient β is 0.1, 0.3, 0.5, 0.7 and 0.9 separately. The results are shown in Figure 4.

We can see in Figure 4, when the datasets have less service objects, the comprehensive selection or subjective selection has high service matching rate successfully. With the data increases, the comprehensive weight matching rate increases, whereas the cloud service match-making rate decreases based on the subjective preference information.

In [12] , the author proposed an analytical framework to explore the significant factors affecting the adoption of SaaS for enterprise users using rough set theory. The main contribution is to mine the important factors. Although our work is similar it in context, but our study goes to one step further, mining the significant factors in assessing cloud service providers (shown in Table 3), for example. There are six factors (CI, SC, PT, S, TCO, BI) in the information system of cloud service provider. It can mine four factors (CI, SC, PT, S) which are the important influence factors for evaluating the cloud service providers using the approach in [12] . Beyond that, we can’t get the additional information about the result. However, in our study, we not only can know which factor is the important evaluation index of cloud service provider assessment but also rank them according to their weight, as the result shown in Table 6. Further, we can define a threshold to select evaluation factors at a stretch based on the result to design the evaluation system. In Table 6, we suppose that, for some reason, we need to reduce the number of evaluation factors from 6 to 4. The method in [12] and ours both are effective. That is, the factors TCO and BI would be removed because their influence is smaller than others for evaluating cloud service providers. And if, we need to reduce the number of evaluation factors from 6 to 3, first, we remove the two factors (TCO, BI), after that, we don’t know which factor would be removed among the other four factors (CI, SC, PT, S, TCO, BI) based on the approach in [12] , because there is no more information to guide us to do further. Therefore, the method proposed in [12] is failed in this case. However, in our work, beside removing the two factors (TCO, BI), we can judge easily to remove the factor (CI), because its weight is lower than the other factors’, or according to the rank of factors importance shown in Table 6.

7. Conclusion

To provide a guide choosing the appropriate cloud services for cloud users, we present the rank-making of the parameters importance in cloud services selection and propose a attribute ranking method based on the rough

Figure 4. Cloud service match-making with varies datasets.

Conflicts of Interest

The authors declare no conflicts of interest.

Cite this paper

Liu, Y. , Esseghir, M. and Boulahia, L. (2016) Evaluation of Parameters Importance in Cloud Service Selection Using Rough Sets. Applied Mathematics, 7, 527-541. doi: 10.4236/am.2016.76049.

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