Enhancing air quality classification using a novel discrete learning-based multilayer perceptron model (DMLP)

IF 3 4区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES
M. Ahmadi, M. Khashei, N. Bakhtiarvand
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引用次数: 0

Abstract

Effective utilization of data analysis techniques is paramount in addressing the complex challenges presented by environmental issues. These methodologies empower researchers and practitioners to derive meaningful insights from intricate datasets encompassing air quality, biodiversity, climate change, and other pivotal environmental factors. Through the deployment of robust classification models, such as intelligent classifiers, researchers can accurately classify and predict environmental phenomena. This capability holds significant implications for guiding policy decisions, mitigating environmental risks, and devising sustainable solutions to protect our natural resources and ecosystems. Thus, classification models not only deepen our comprehension of environmental dynamics but also empower proactive measures towards achieving environmental sustainability and resilience amidst global challenges. Intelligent classifiers, distinguished by their exceptional capabilities, have demonstrated superior performance compared to other classification models. However, in all developed intelligent classifiers a similar cost/loss function is implemented in the learning processes, which is continuous and works based on the distance between actual and fitted values. Whereas the nature of the classification is discrete. As a result, in this study, a novel cost/loss function is proposed that in contrast to its conventional version is discrete and works based on the direction. In order to explain the process of the suggested methodology, the feed-forward multilayer perceptrons that are among the most famous intelligent classifiers is considered. In this paper, in order to determine the superiority of the proposed model in the domain of environment, it is implemented on some benchmark data sets which is related to air quality. Numerical results indicate that the performance of the proposed model is better than the conventional multilayer perceptrons in whole benchmark data sets. In addition, numerical results clarify that the developed discrete learning-based multilayer perceptron classifier can averagely gain an 87.68% classification rate, which points to more than 9% improvement over its conventional version.

Abstract Image

利用基于离散学习的新型多层感知器模型(DMLP)加强空气质量分类
有效利用数据分析技术对于应对环境问题带来的复杂挑战至关重要。这些方法使研究人员和从业人员能够从包括空气质量、生物多样性、气候变化和其他关键环境因素在内的复杂数据集中获得有意义的见解。通过部署强大的分类模型(如智能分类器),研究人员可以准确地对环境现象进行分类和预测。这种能力对于指导政策决策、降低环境风险以及制定可持续的解决方案来保护我们的自然资源和生态系统具有重要意义。因此,分类模型不仅能加深我们对环境动态的理解,还能采取积极主动的措施,在全球挑战中实现环境的可持续发展和恢复能力。与其他分类模型相比,智能分类器以其非凡的能力而与众不同,表现出卓越的性能。然而,所有已开发的智能分类器在学习过程中都会执行类似的成本/损失函数,该函数是连续的,基于实际值与拟合值之间的距离。而分类的本质是离散的。因此,本研究提出了一种新的成本/损失函数,与传统的成本/损失函数不同,它是离散的,基于方向起作用。为了解释所建议方法的过程,本文考虑了前馈多层感知器,它是最著名的智能分类器之一。为了确定所建议的模型在环境领域的优越性,本文在一些与空气质量相关的基准数据集上实施了该模型。数值结果表明,在整个基准数据集中,所提模型的性能优于传统的多层感知器。此外,数值结果表明,所开发的基于离散学习的多层感知器分类器的平均分类率为 87.68%,比其传统版本提高了 9% 以上。
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来源期刊
CiteScore
5.60
自引率
6.50%
发文量
806
审稿时长
10.8 months
期刊介绍: International Journal of Environmental Science and Technology (IJEST) is an international scholarly refereed research journal which aims to promote the theory and practice of environmental science and technology, innovation, engineering and management. A broad outline of the journal''s scope includes: peer reviewed original research articles, case and technical reports, reviews and analyses papers, short communications and notes to the editor, in interdisciplinary information on the practice and status of research in environmental science and technology, both natural and man made. The main aspects of research areas include, but are not exclusive to; environmental chemistry and biology, environments pollution control and abatement technology, transport and fate of pollutants in the environment, concentrations and dispersion of wastes in air, water, and soil, point and non-point sources pollution, heavy metals and organic compounds in the environment, atmospheric pollutants and trace gases, solid and hazardous waste management; soil biodegradation and bioremediation of contaminated sites; environmental impact assessment, industrial ecology, ecological and human risk assessment; improved energy management and auditing efficiency and environmental standards and criteria.
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