Abstract
Effective vector representation has been proven useful for transaction classification and clustering tasks in Cyber-Physical Systems. Traditional methods use heuristic-based approaches and different pruning strategies to discover the required patterns efficiently. With the extensive and high dimensional availability of transactional data in cyber-physical systems, traditional methods that used frequent itemsets (FIs) as features suffer from dimensionality, sparsity, and privacy issues. In this paper, we first propose a federated learning-based embedding model for the transaction classification task. The model takes transaction data as a set of frequent item-sets. Afterward, the model can learn low dimensional continuous vectors by preserving the frequent item-sets contextual relationship. We perform an in-depth experimental analysis on the number of high dimensional transactional data to verify the developed models with attention-based mechanism and federated learning. From the results, it can be seen that the designed model can help and improve the decision boundary by reducing the global loss function while maintaining both security and privacy.
Highlights
Data is deemed as a major asset to explore different facts about the entities associated with it
The scientific community has been interested in data mining techniques that pertain to pattern mining like frequent pattern mining (FPM) [2], association rule mining (ARM) [3], frequent episode mining (FEM) [4], and sequential pattern mining (SPM) [5]
We demonstrate that the developed embedding model helps in transaction classification tasks on several benchmark datasets
Summary
Data is deemed as a major asset to explore different facts about the entities associated with it. Various real-life applications demand to mine interesting patterns from data [1]. The scientific community has been interested in data mining techniques that pertain to pattern mining like frequent pattern mining (FPM) [2], association rule mining (ARM) [3], frequent episode mining (FEM) [4], and sequential pattern mining (SPM) [5]. These techniques’ prime concern is to mine patterns from real-world applications by harnessing co-occurrence, frequency, and interestingness measures
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