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Academic Journal of Computing & Information Science, 2025, 8(6); doi: 10.25236/AJCIS.2025.080608.

Deep Learning Error Minimization System for Real-Time Big Data Analysis in Mobile Applications

Author(s)

Yang Qing, Zhou Jing

Corresponding Author:
Yang Qing
Affiliation(s)

University of Science and Technology Liaoning, Anshan, Liaoning, China

Abstract

This paper presents a novel deep learning error minimization system designed to enhance the efficiency, adaptability, and accuracy of real-time big data analysis in mobile applications. Traditional deep learning systems face limitations such as the need for large labeled datasets, high computational complexity, and challenges in generalizing to new tasks and dynamic data. The proposed system addresses these limitations through a hybrid neural network architecture that integrates convolutional neural networks (CNNs) and recurrent neural networks (RNNs), a dynamic error feedback mechanism using reinforcement learning, and a lightweight transfer learning module. The system also includes modules for data preprocessing, augmentation, and model evaluation. Case studies demonstrate the system's effectiveness in real-time data analysis for applications such as financial market analysis, showcasing its potential to significantly improve performance and user experience in mobile applications.

Keywords

Deep Learning, Error Minimization, Real-Time Big Data Analysis, Mobile Applications, Hybrid Neural Networks, Dynamic Error Feedback, Transfer Learning

Cite This Paper

Yang Qing, Zhou Jing. Deep Learning Error Minimization System for Real-Time Big Data Analysis in Mobile Applications. Academic Journal of Computing & Information Science (2025), Vol. 8, Issue 6: 64-73. https://doi.org/10.25236/AJCIS.2025.080608.

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