Affiliation:
1. São Paulo State University (UNESP), Institute of Science and Technology
2. Sorocaba University (UNISO)
3. São Paulo State University (UNESP)
Abstract
Human intervention on vegetation cover has always had a negative impact on the environment, directly affecting the quality of life in urban areas. Therefore, this study aimed to develop a methodology for the construction of an urban environmental quality indicator (UEQI) that could reflect the environmental quality of urban areas considering the vegetation conditions to which the resident population is exposed. For this, the method sought to integrate data on demographic density (Dd), leaf area index (LAI), normalized difference vegetation index (NDVI), and surface temperature (St). The Mamdani fuzzy inference system was used to generate a rule base containing 108 variations and a defuzzed output with five condition classes, ranging from very bad to excellent. The results showed that the studied area is characterized by a very bad to good UEQI, with most neighbourhoods having poor conditions (64.51%) and only two with good conditions. It was found that in general the studied area has unsatisfactory environmental quality, showing the need for initiatives aimed at urban afforestation in order to improve the quality of life for the studied population. It can be concluded that UEQI proved to be an efficient tool to identify priority areas for the planning and management of vegetation cover in urbanized areas, enabling the improvement of people's living conditions.
Publisher
Russian Geographical Society
Subject
Environmental Science (miscellaneous),Geography, Planning and Development
Reference63 articles.
1. Allen R., Bastiaanssen W., Wartes R., Tasumi M. and Trezza R. (2002). Surface energy balance algorithms for land (SEBAL), Idaho implementation - Advanced training and user manual, version 1.0. Available at: http://www.posmet.ufv.br/wp-content/uploads/2016/09/MET-479-Waters-et-al-SEBAL.pdf [Accessed 20 Mar. 2019].
2. Amorim M., Quenol V. and Sant'ana Neto, J. (2009). Caracteristicas das ilhas de calor em cidades de porte medio: exemplos de Presidente Prudente (Brasil) e Rennes (Franga), Confins, 7, 116, DOI: 10.4000/confins.6070.
3. Amorim M. (2017). Detecgao Remota de Ilhas de Calor Superficiais: Exemplos de Cidades de Porte Medio e Pequeno do Ambiente Tropical, Brasil. Finisterra, 105, 111-133, DOI: 10.18055/Finis6888.
4. Artis D.A. and Carnahan W. H. (1982). Survey of emissivity variability in thermography of urban areas. Remote Sensing of Environment, 12, 313-329, DOI: 10.1016/0034-4257(82)90043-8.
5. Avila M. and Pancher A. (2015). Estudo das Areas Verdes Urbanas como Indicador de Qualidade Ambiental no Municipio de Americana -SP. Rev. Bras. Cartogr., 67(3), 527-544. Available at: http://www.seer.ufu.br/index.php/revistabrasileiracartografia/article/view/44648 [Accessed 2 May 2019].
Cited by
4 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献