A User-Centered Framework for Data Privacy Protection Using Large Language Models and Attention Mechanisms

Zhou, Shutian; Zhou, Zizhe; Wang, Chenxi; Liang, Yuzhe; Wang, Liangyu; Zhang, Jiahe; Zhang, Jinming; Lv, Chunli

doi:10.3390/app14156824

Applied Sciences

2024

DOI: 10.3390/app14156824

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A User-Centered Framework for Data Privacy Protection Using Large Language Models and Attention Mechanisms

Shutian Zhou,

Zizhe Zhou,

Chenxi Wang

et al.

Abstract: This paper introduces a user-centered data privacy protection framework utilizing large language models (LLMs) and user attention mechanisms, which are tailored to address urgent privacy concerns in sensitive data processing domains like financial computing and facial recognition. The innovation lies in a novel user attention mechanism that dynamically adjusts attention weights based on data characteristics and user privacy needs, enhancing the ability to identify and protect sensitive information effectively.… Show more

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A Methodology Based on Deep Learning for Contact Detection in Radar Images

Gonzales Martínez,

Moreno,

Rotta Saavedra

et al. 2024

Applied Sciences

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Ship detection, a crucial task, relies on the traditional CFAR (Constant False Alarm Rate) algorithm. However, this algorithm is not without its limitations. Noise and clutter in radar images introduce significant variability, hampering the detection of objects on the sea surface. The algorithm’s theoretically Constant False Alarm Rates are not upheld in practice, particularly when conditions change abruptly, such as with Beaufort wind strength. Moreover, the high computational cost of signal processing adversely affects the detection process’s efficiency. In previous work, a four-stage methodology was designed: The first preprocessing stage consisted of image enhancement by applying convolutions. Labeling and training were performed in the second stage using the Faster R-CNN architecture. In the third stage, model tuning was accomplished by adjusting the weight initialization and optimizer hyperparameters. Finally, object filtering was performed to retrieve only persistent objects. This work focuses on designing a specific methodology for ship detection in the Peruvian coast using commercial radar images. We introduce two key improvements: automatic cropping and a labeling interface. Using artificial intelligence techniques in automatic cropping leads to more precise edge extraction, improving the accuracy of object cropping. On the other hand, the developed labeling interface facilitates a comparative analysis of persistence in three consecutive rounds, significantly reducing the labeling times. These enhancements increase the labeling efficiency and enhance the learning of the detection model. A dataset consisting of 60 radar images is used for the experiments. Two classes of objects are considered, and cross-validation is applied in the training and validation models. The results yield a value of 0.0372 for the cost function, a recovery rate of 94.5%, and an accuracy rate of 95.1%, respectively. This work demonstrates that the proposed methodology can generate a high-performance model for contact detection in commercial radar images.

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A Methodology Based on Deep Learning for Contact Detection in Radar Images

Gonzales Martínez,

Moreno,

Rotta Saavedra

et al. 2024

Applied Sciences

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A User-Centered Framework for Data Privacy Protection Using Large Language Models and Attention Mechanisms

Cited by 1 publication

References 33 publications

A Methodology Based on Deep Learning for Contact Detection in Radar Images

A Methodology Based on Deep Learning for Contact Detection in Radar Images

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