Data-Centric AI in the Era of Large Volumes: Improving Model Outcomes through Data Quality Engineering
DOI:
https://doi.org/10.63282/3117-5481/AIJCST-V7I4P112Keywords:
Data-Centric AI, Data Quality Engineering, Big Data, AI Model Performance, Data Labeling, Data Cleaning, Feature Engineering, Data Governance, Model Retraining, Data Validation, Data Pipelines, Machine Learning, AI ReliabilityAbstract
Nowadays, the whole AI system’ success is determined not only by algorithms but also, and even more importantly, by the data quality that the systems use. The rise in the amount, speed, and diversity of data has reached the point where it is no longer possible to rely only on a model-centric approach. This article tracks the extent of the growth of data-centric AI which addresses the improvement of the data itself as the main lever for better model outcomes. At the core of this transformation lies data quality engineering—a highly disciplined and oftentimes neglected profession that goes way beyond performing the research on datasets and running formal verification tests, but it is basically the very essence of completeness, consistency, and context appropriateness of the datasets in question prior to their being used in any modeling work. In high-volume environments that are prone to falling, minor inconsistencies may become a big headache and using the preventative data hygiene approach in this context becomes indispensable. The paper looks into ways of how implementing data quality pipelines, anomaly detection, labeling integrity checks, and feedback loops into AI workflows not only makes models more reliable but also minimizes retraining costs and shortens deployment cycles. The embedding of data quality engineering into the development lifecycle has facilitated organizations™ transition from being reactive to the failures to a culture of continuous improvement driven by trusted data. This transformation allows teams to focus more on innovation and less on debugging. In the final analysis, this mind shift paper argues that in the world of such a massive increase of data, a data-centric approach—rooted in engineering discipline—is the most effective way of achieving scalable and robust AI.
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