A Correlation Based Recommendation System for Large Data Sets
Authors: Pandove, D. and Malhi, A.
Journal: Journal of Grid Computing
Volume: 19
Issue: 4
eISSN: 1572-9184
ISSN: 1570-7873
DOI: 10.1007/s10723-021-09585-9
Abstract:Correlation determination brings out relationships in data that had not been seen before and it is imperative to successfully use the power of correlations for data mining. In this paper, we have used the concepts of correlations to cluster data, and merged it with recommendation algorithms. We have proposed two correlation clustering algorithms (RBACC and LGBACC), that are based on finding Spearman’s rank correlation coefficient among data points, and using dimensionality reduction approach (PCA) along with graph theory respectively, to produce high quality hierarchical clusters. Both these algorithms have been tested on real life data (New York yellow cabs dataset taken from http://www.nyc.gov), using distributed and parallel computing (Spark and R). They are found to be scalable and perform better than the existing hierarchical clustering algorithms. These two approaches have been used to replace similarity measures in recommendation algorithms and generate a correlation clustering based recommendation system model. We have combined the power of correlation analysis with that of prediction analysis to propose a better recommendation system. It is found that this model makes better quality recommendations as compared to the random recommendation model. This model has been validated using a real time, large data set (MovieLens dataset, taken from http://grouplens.org/datasets/movielens/latest). The results show that combining correlated points with the predictive power of recommendation algorithms, produce better quality recommendations which are faster to compute. LGBACC has approximately 25% better prediction capability but at the same time takes significantly more prediction time compared to RBACC.
https://eprints.bournemouth.ac.uk/36176/
Source: Scopus
A Correlation Based Recommendation System for Large Data Sets
Authors: Pandove, D. and Malhi, A.
Journal: JOURNAL OF GRID COMPUTING
Volume: 19
Issue: 4
eISSN: 1572-9184
ISSN: 1570-7873
DOI: 10.1007/s10723-021-09585-9
https://eprints.bournemouth.ac.uk/36176/
Source: Web of Science (Lite)
A Correlation Based Recommendation System for Large Data Sets
Authors: Pandove, D. and Malhi, A.
Journal: Journal of Grid Computing
Volume: 19
Issue: 4
ISSN: 1570-7873
Abstract:Correlation determination brings out relationships in data that had not been seen before and it is imperative to successfully use the power of correlations for data mining. In this paper, we have used the concepts of correlations to cluster data, and merged it with recommendation algorithms. We have proposed two correlation clustering algorithms (RBACC and LGBACC), that are based on finding Spearman’s rank correlation coefficient among data points, and using dimensionality reduction approach (PCA) along with graph theory respectively, to produce high quality hierarchical clusters. Both these algorithms have been tested on real life data (New York yellow cabs dataset taken from http://www.nyc.gov), using distributed and parallel computing (Spark and R). They are found to be scalable and perform better than the existing hierarchical clustering algorithms. These two approaches have been used to replace similarity measures in recommendation algorithms and generate a correlation clustering based recommendation system model. We have combined the power of correlation analysis with that of prediction analysis to propose a better recommendation system. It is found that this model makes better quality recommendations as compared to the random recommendation model. This model has been validated using a real time, large data set (MovieLens dataset, taken from http://grouplens.org/datasets/movielens/latest). The results show that combining correlated points with the predictive power of recommendation algorithms, produce better quality recommendations which are faster to compute. LGBACC has approximately 25% better prediction capability but at the same time takes significantly more prediction time compared to RBACC..
https://eprints.bournemouth.ac.uk/36176/
Source: BURO EPrints