The Empirical Investigation of Knowledge Hiding and In-role Behavior

This research was intended to investigate the connection between Knowledge Hiding and In-role Behavior. The relationship between independent and dependent variables was calculated by the Pearson correlation and simple regression analysis. The data was randomly collected through a self-administered questionnaire from 129 staff working in private sector universities.  This was a cross-sectional analysis and the findings showed that Knowledge Hiding negatively affect the in-role behavior of employees (r = 41.6, β = -.645, t = 9.51, p < 0.005). The results of this study suggested that universities need to focus on the Knowledge Hiding Behavior of employees in order to achieve their objectives and improve quality

Coefficient-based exact approach for frequent itemset hiding

Concealing sensitive relationships before sharing a database is of utmost importance in many circumstances. This implies to hide the frequent itemsets corresponding to sensitive association rules by removing some items of the database. Research efforts generally aim at finding out more effectivemethods in terms of convenience, execution time and side-effect. This paper presents a practical approach for hiding sensitive patterns while allowing as much nonsensitive patterns as possible in the sanitized database. We model the itemset hiding problem as integer programming whereas the objective coefficients allow finding out a solution with minimum loss of nonsensitive itemsets. We evaluate our method using three real datasets and compared the results with a previous work. The results show that information loss is dramatically minimized without sacrificing the accuracy

Investigations in Privacy Preserving Data Mining

Data Mining, Data Sharing and Privacy-Preserving are fast emerging as a field of the high level of the research study. A close review of the research based on Privacy Preserving Data Mining revealed the twin fold problems, first is the protection of private data (Data Hiding in Database) and second is the protection of sensitive rules (Knowledge) ingrained in data (Knowledge Hiding in the database). The first problem has its impetus on how to obtain accurate results even when private data is concealed. The second issue focuses on how to protect sensitive association rule contained in the database from being discovered, while non-sensitive association rules can still be mined with traditional data mining projects. Undoubtedly, performance is a major concern with knowledge hiding techniques. This paper focuses on the description of approaches for Knowledge Hiding in the database as well as discuss issues and challenges about the development of an integrated solution for Data Hiding in Database and Knowledge Hiding in Database. This study also highlights directions for the future studies so that suggestive pragmatic measures can be incorporated in ongoing research process on hiding sensitive association rules

Hiding sensitive knowledge without side effects

Sensitive knowledge hiding in large transactional databases is one of the major goals of privacy preserving data mining. However, it is only recently that researchers were able to identify exact solutions for the hiding of knowledge, depicted in the form of sensitive frequent itemsets and their related association rules. Exact solutions allow for the hiding of vulnerable knowledge without any critical compromises, such as the hiding of nonsensitive patterns or the accidental uncovering of infrequent itemsets, amongst the frequent ones, in the sanitized outcome. In this paper, we highlight the process of border revision, which plays a significant role towards the identification of exact hiding solutions, and we provide efficient algorithms for the computation of the revised borders. Furthermore, we review two algorithms that identify exact hiding solutions, and we extend the functionality of one of them to effectively identify exact solutions for a wider range of problems (than its original counterpart). Following that, we introduce a novel framework for decomposition and parallel solving of hiding problems, which are handled by each of these approaches. This framework improves to a substantial degree the size of the problems that both algorithms can handle and significantly decreases their runtime. Through experimentation, we demonstrate the effectiveness of these approaches toward providing high quality knowledge hiding solutions