Vol. 3 No. 2 (2023): Journal of AI-Assisted Scientific Discovery
Articles

Foundation Models: The New AI Paradigm for Big Data Analytics

Naresh Dulam
Vice President Sr Lead Software Engineer, JP Morgan Chase, USA
Abhilash Katari
Engineering Lead, Persistent Systems Inc, USA
Madhu Ankam
Vice President Sr Lead Software Engineer, JP Morgan Chase, USA
Cover

Published 05-10-2023

Keywords

  • Foundation models,
  • big data analytics

How to Cite

[1]
Naresh Dulam, Abhilash Katari, and Madhu Ankam, “Foundation Models: The New AI Paradigm for Big Data Analytics ”, Journal of AI-Assisted Scientific Discovery, vol. 3, no. 2, pp. 639–664, Oct. 2023, Accessed: Dec. 24, 2024. [Online]. Available: https://scienceacadpress.com/index.php/jaasd/article/view/231

Abstract

Foundation models are reshaping artificial intelligence, unlocking unprecedented capabilities in big data analytics. These models, pre-trained on massive, diverse datasets, can be fine-tuned for specific tasks while maintaining a versatile, general-purpose functionality. Unlike traditional AI systems designed for singular, narrowly focused applications, foundation models excel in processing complex, unstructured data and extracting meaningful insights. Their architecture, often based on transformers, enables them to capture intricate patterns and relationships across vast datasets, making them exceptionally powerful for tasks like natural language understanding, image recognition, & predictive analytics. Their impact spans diverse industries such as healthcare, finance, retail, and manufacturing, where they automate complex workflows, enhance decision-making, & uncover hidden trends. Foundation models' versatility allows organizations to harness data more effectively, turning challenges posed by information overload into opportunities for innovation and efficiency. By enabling more intelligent analytics, they support deeper contextual understanding, improve operational agility, and drive strategic outcomes. However, their immense scale & computational requirements introduce significant challenges, including accessibility, environmental impact, and concerns about bias in the underlying data. While interpretability remains an ongoing area of research, these models' ability to generalize across domains signals a paradigm shift in AI. They redefine how organizations interact with data, making it possible to extract actionable insights from the vast, complex, and fragmented information ecosystems that define the modern world. This evolution underscores the potential for foundation models to become indispensable tools for navigating an era defined by data-driven decision-making, offering a transformative approach to analytics that moves beyond traditional boundaries.

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