English

CAE: Character-Level Autoencoder for Non-Semantic Relational Data Grouping

Machine Learning 2025-11-12 v1

Abstract

Enterprise relational databases increasingly contain vast amounts of non-semantic data - IP addresses, product identifiers, encoded keys, and timestamps - that challenge traditional semantic analysis. This paper introduces a novel Character-Level Autoencoder (CAE) approach that automatically identifies and groups semantically identical columns in non-semantic relational datasets by detecting column similarities based on data patterns and structures. Unlike conventional Natural Language Processing (NLP) models that struggle with limitations in semantic interpretability and out-of-vocabulary tokens, our approach operates at the character level with fixed dictionary constraints, enabling scalable processing of large-scale data lakes and warehouses. The CAE architecture encodes text representations of non-semantic relational table columns and extracts high-dimensional feature embeddings for data grouping. By maintaining a fixed dictionary size, our method significantly reduces both memory requirements and training time, enabling efficient processing of large-scale industrial data environments. Experimental evaluation demonstrates substantial performance gains: our CAE approach achieved 80.95% accuracy in top 5 column matching tasks across relational datasets, substantially outperforming traditional NLP approaches such as Bag of Words (47.62%). These results demonstrate its effectiveness for identifying and clustering identical columns in relational datasets. This work bridges the gap between theoretical advances in character-level neural architectures and practical enterprise data management challenges, providing an automated solution for schema understanding and data profiling of non-semantic industrial datasets at scale.

Keywords

Cite

@article{arxiv.2511.07657,
  title  = {CAE: Character-Level Autoencoder for Non-Semantic Relational Data Grouping},
  author = {Veera V S Bhargav Nunna and Shinae Kang and Zheyuan Zhou and Virginia Wang and Sucharitha Boinapally and Michael Foley},
  journal= {arXiv preprint arXiv:2511.07657},
  year   = {2025}
}
R2 v1 2026-07-01T07:30:54.931Z