Framework for Quality Ranking of Components in Cloud Computing: Regressive Rank

As the popularity of cloud computing is increasing there is an urgent requirement of developing highly efficient and highly qualitative cloud applications (CA). Hence, it be-comes a big research problem. A recommender system recommends the suitable item to the user and almost all the systems provide a rating score for preference. Traditionally, algorithms predicts the ratings that a user should give to the unrated components to queue the item in recommended list. To select an optimal candidate from a set of function-ally equivalent candidates is crucial through approaches that follow a framework for component quality ranking. More-over, such framework helps in detecting the poor performing candidates from a highly distributed cloud applications. In this paper a novel technique is proposed to provide personalized component ranking for designers by employing the past usage of components by different users. In this approach the similarity between the users is measured based on their rankings for functionally equivalent components set instead of their rating values. In this approach no additional invocation of cloud component is required. Experimental results on real world web-service invocations data set shows that the proposed approach outperforms the previous approaches.

[1]  Qiang Yang,et al.  EigenRank: a ranking-oriented approach to collaborative filtering , 2008, SIGIR '08.

[2]  Sateesh Kumar Peddoju,et al.  A model to find optimal percentage of training and testing data for efficient ECG analysis using neural network , 2018, Int. J. Syst. Assur. Eng. Manag..

[3]  Tushar Bhardwaj,et al.  Steps Towards Web Ubiquitous Computing , 2012, SocProS.

[4]  Millie Pant,et al.  PSO ingrained Artificial Bee Colony algorithm for solving continuous optimization problems , 2011, 2011 IEEE International Conference on Computer Applications and Industrial Electronics (ICCAIE).

[5]  Jaana Kekäläinen,et al.  Cumulated gain-based evaluation of IR techniques , 2002, TOIS.

[6]  Michael R. Lyu,et al.  Effective missing data prediction for collaborative filtering , 2007, SIGIR.

[7]  Vincenzo Grassi,et al.  A Modeling Approach to Analyze the Impact of Error Propagation on Reliability of Component-Based Systems , 2007, CBSE.

[8]  Tarun Kumar Sharma,et al.  "A Safer Cloud", Data Isolation and Security by Tus-Man Protocol , 2012, SocProS.

[9]  Mohit Kumar,et al.  Megh: A Private Cloud Provisioning Various IaaS and SaaS , 2018 .

[10]  Tarun Kumar Sharma,et al.  Social Engineering Prevention by Detecting Malicious URLs Using Artificial Bee Colony Algorithm , 2013, SocProS.

[11]  Subhash Chander Sharma,et al.  Internet of Things: Route Search Optimization Applying Ant Colony Algorithm and Theory of Computation , 2014, SocProS.

[12]  Greg Linden,et al.  Amazon . com Recommendations Item-to-Item Collaborative Filtering , 2001 .

[13]  John Riedl,et al.  An algorithmic framework for performing collaborative filtering , 1999, SIGIR '99.

[14]  Anthony Jameson,et al.  User Modeling and User-Adapted Interaction , 2004, User Modeling and User-Adapted Interaction.

[15]  Piero A. Bonatti,et al.  On optimal service selection , 2005, WWW '05.

[16]  David Heckerman,et al.  Empirical Analysis of Predictive Algorithms for Collaborative Filtering , 1998, UAI.

[17]  Yoram Singer,et al.  Learning to Order Things , 1997, NIPS.

[18]  Jun Wang,et al.  Unifying user-based and item-based collaborative filtering approaches by similarity fusion , 2006, SIGIR.

[19]  Subhash Chander Sharma,et al.  An autonomic resource provisioning framework for efficient data collection in cloudlet-enabled wireless body area networks: a fuzzy-based proactive approach , 2019, Soft Comput..

[20]  Baogang Wei,et al.  CARES: a ranking-oriented CADAL recommender system , 2009, JCDL '09.

[21]  George Karypis,et al.  Item-based top-N recommendation algorithms , 2004, TOIS.

[22]  Robin D. Burke,et al.  Hybrid Recommender Systems: Survey and Experiments , 2002, User Modeling and User-Adapted Interaction.

[23]  Subhash Chander Sharma,et al.  Cloud-WBAN: An experimental framework for Cloud-enabled Wireless Body Area Network with efficient virtual resource utilization , 2018, Sustain. Comput. Informatics Syst..

[24]  Ajay Chaudhary,et al.  A Simulation Study of Response Times in Cloud Environment for IoT-Based Healthcare Workloads , 2017, 2017 IEEE 14th International Conference on Mobile Ad Hoc and Sensor Systems (MASS).

[25]  Anne H. H. Ngu,et al.  QoS-aware middleware for Web services composition , 2004, IEEE Transactions on Software Engineering.

[26]  Subhash Chander Sharma,et al.  Fuzzy logic-based elasticity controller for autonomic resource provisioning in parallel scientific applications: A cloud computing perspective , 2018, Comput. Electr. Eng..

[27]  Zibin Zheng,et al.  Collaborative reliability prediction of service-oriented systems , 2010, 2010 ACM/IEEE 32nd International Conference on Software Engineering.

[28]  Albert Benveniste,et al.  Probabilistic QoS and Soft Contracts for Transaction-Based Web Services Orchestrations , 2008, IEEE Trans. Serv. Comput..

[29]  Zibin Zheng,et al.  CloudRank: A QoS-Driven Component Ranking Framework for Cloud Computing , 2010, 2010 29th IEEE Symposium on Reliable Distributed Systems.

[30]  Tao Yu,et al.  Efficient algorithms for Web services selection with end-to-end QoS constraints , 2007, TWEB.

[31]  Tushar Bhardwaj,et al.  An Efficient Elasticity Mechanism for Server-Based Pervasive Healthcare Applications in Cloud Environment , 2017, 2017 IEEE 19th International Conference on High Performance Computing and Communications Workshops (HPCCWS).