Unveiling Data Fairness Functional Requirements in Big Data Analytics Through Data Mapping and Classification Analysis

Q3 Mathematics

International Journal of Sensors, Wireless Communications and Control Pub Date : 2024-07-19 DOI:10.2174/0122103279312138240625052021

P. Hemalatha, J. Lavanya

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Abstract

In the realm of Big Data Analytics, ensuring the fairness of data-driven decisionmaking processes is imperative. This abstract introduces the Learning Embedded Fairness Interpretation (LEFI) Model, a novel approach designed to uncover and address data fairness functional requirements with an exceptional accuracy rate of 97%. The model harnesses advanced data mapping and classification analysis techniques, employing Explainable-AI (xAI) for transparent insights into fairness within large datasets The LEFI Model excels in navigating diverse datasets by mapping data elements to discern patterns contributing to biases. Through systematic classification analysis, LEFI identifies potential sources of unfairness, achieving an accuracy rate of 97% in discerning and addressing these issues. This high accuracy empowers data analysts and stakeholders with confidence in the model's assessments, facilitating informed and reliable decision-making. Crucially, the LEFI Model's implementation in Python leverages the power of this versatile programming language. The Python implementation seamlessly integrates advanced mapping, classification analysis, and xAI to provide a robust and efficient solution for achieving data fairness in Big Data Analytics. This implementation ensures accessibility and ease of adoption for organizations aiming to embed fairness into their data-driven processes. The LEFI Model, with its 97% accuracy, exemplifies a comprehensive solution for data fairness in Big Data Analytics. Moreover, by combining advanced technologies and implementing them in Python, LEFI stands as a reliable framework for organizations committed to ethical data usage. The model not only contributes to the ongoing dialogue on fairness but also sets a new standard for accuracy and transparency in the analytics pipeline, advocating for a more equitable future in the realm of Big Data Analytics.

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通过数据映射和分类分析揭示大数据分析中的数据公平性功能要求

在大数据分析领域，确保数据驱动决策过程的公平性势在必行。本摘要介绍了学习嵌入式公平性解释（LEFI）模型，这是一种新颖的方法，旨在发现和解决数据公平性功能要求，准确率高达 97%。该模型利用先进的数据映射和分类分析技术，采用可解释人工智能（xAI），以透明的方式深入了解大型数据集中的公平性。LEFI模型通过映射数据元素来识别导致偏差的模式，在浏览各种数据集方面表现出色。通过系统分类分析，LEFI 可识别潜在的不公平来源，在识别和解决这些问题方面的准确率高达 97%。如此高的准确率增强了数据分析师和利益相关者对模型评估的信心，有助于做出明智可靠的决策。最重要的是，LEFI 模型在 Python 中的实现充分利用了这一通用编程语言的强大功能。Python 实现无缝集成了高级映射、分类分析和 xAI，为在大数据分析中实现数据公平性提供了一个强大而高效的解决方案。LEFI 模型的准确率高达 97%，是大数据分析中数据公平性综合解决方案的典范。此外，通过结合先进的技术并在 Python 中实现这些技术，LEFI 成为致力于合乎道德的数据使用的组织的可靠框架。该模型不仅有助于正在进行的关于公平性的对话，还为分析管道中的准确性和透明度设定了新的标准，倡导在大数据分析领域实现更加公平的未来。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Sensors, Wireless Communications and Control Engineering-Electrical and Electronic Engineering

CiteScore

2.20

自引率

0.00%

发文量

期刊介绍： International Journal of Sensors, Wireless Communications and Control publishes timely research articles, full-length/ mini reviews and communications on these three strongly related areas, with emphasis on networked control systems whose sensors are interconnected via wireless communication networks. The emergence of high speed wireless network technologies allows a cluster of devices to be linked together economically to form a distributed system. Wireless communication is playing an increasingly important role in such distributed systems. Transmitting sensor measurements and control commands over wireless links allows rapid deployment, flexible installation, fully mobile operation and prevents the cable wear and tear problem in industrial automation, healthcare and environmental assessment. Wireless networked systems has raised and continues to raise fundamental challenges in the fields of science, engineering and industrial applications, hence, more new modelling techniques, problem formulations and solutions are required.